Project description:Cytoplasmic polyadenylation is a mechanism to promote mRNA translation in a wide variety of biological contexts. A canonical complex centered around the conserved RNA-binding protein family CPEB has been shown to be responsible for this process. We have previously reported evidence for an alternative non-canonical, CPEB-independent complex in Drosophila, of which the RNA-interference factor Dicer-2 is a component. Here, we investigate Dicer-2 mRNA targets and protein co-factors in cytoplasmic polyadenylation. Using RIP-Seq analysis we identify hundreds of novel Dicer-2 target transcripts, ~50% 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 revealed Ataxin-2 and Twenty-four among the high-confidence interactors of Dicer-2. Functional analysis indicate that both factors form an RNA-independent complex with Dicer-2, and are required for cytoplasmic polyadenylation of Dicer-2 targets. Our results reveal the composition of a novel cytoplasmic polyadenylation complex that operates during Drosophila early embryogenesis.

Project description:The translational reactivation of maternal mRNAs encoding the drivers of vertebrate meiosis is accomplished mainly by cytoplasmic polyadenylation. The Cytoplasmic Polyadenylation Elements (CPEs) present in the 3’ UTR of these transcripts, together with their cognate CPE-binding proteins (CPEBs), define a combinatorial code that determines the timing and extent of translational activation upon meiosis resumption. In addition, the RNA-binding protein Musashi1 (Msi1) regulates the polyadenylation of CPE-containing mRNAs by an as yet undefined CPEB-dependent or -independent mechanism. Here we show that Msi1 alone does not support cytoplasmic polyadenylation, but its binding triggers the remodeling of RNA structure, thereby exposing adjacent CPEs and stimulating polyadenylation. Thus, Msi1 directs the preferential use of specific CPEs, which in turn affects the timing and extent of polyadenylation during meiotic progression. Genome-wide analysis of CPEB1- and Msi-associated mRNAs identified 491 common targets, thus revealing a new layer of CPE-mediated translational control.

Project description:The translational reactivation of maternal mRNAs encoding the drivers of vertebrate meiosis is accomplished mainly by cytoplasmic polyadenylation. The Cytoplasmic Polyadenylation Elements (CPEs) present in the 3’ UTR of these transcripts, together with their cognate CPE-binding proteins (CPEBs), define a combinatorial code that determines the timing and extent of translational activation upon meiosis resumption. In addition, the RNA-binding protein Musashi1 (Msi1) regulates the polyadenylation of CPE-containing mRNAs by an as yet undefined CPEB-dependent or -independent mechanism. Here we show that Msi1 alone does not support cytoplasmic polyadenylation, but its binding triggers the remodeling of RNA structure, thereby exposing adjacent CPEs and stimulating polyadenylation. Thus, Msi1 directs the preferential use of specific CPEs, which in turn affects the timing and extent of polyadenylation during meiotic progression. Genome-wide analysis of CPEB1- and Msi-associated mRNAs identified 491 common targets, thus revealing a new layer of CPE-mediated translational control.

Project description:The translational reactivation of maternal mRNAs encoding the drivers of vertebrate meiosis is accomplished mainly by cytoplasmic polyadenylation. The Cytoplasmic Polyadenylation Elements (CPEs) present in the 3’ UTR of these transcripts, together with their cognate CPE-binding proteins (CPEBs), define a combinatorial code that determines the timing and extent of translational activation upon meiosis resumption. In addition, the RNA-binding protein Musashi1 (Msi1) regulates the polyadenylation of CPE-containing mRNAs by an as yet undefined CPEB-dependent or -independent mechanism. Here we show that Msi1 alone does not support cytoplasmic polyadenylation, but its binding triggers the remodeling of RNA structure, thereby exposing adjacent CPEs and stimulating polyadenylation. Thus, Msi1 directs the preferential use of specific CPEs, which in turn affects the timing and extent of polyadenylation during meiotic progression. Genome-wide analysis of CPEB1- and Msi-associated mRNAs identified 491 common targets, thus revealing a new layer of CPE-mediated translational control.

Project description:Localized protein translation is critical in many biological contexts, particularly in highly polarized cells, such as neurons, to regulate gene expression in a spatiotemporal manner. The cytoplasmic polyadenylation element-binding (CPEB) family of RNA-binding proteins has emerged as a key regulator of mRNA transport and local translation required for early embryonic development, synaptic plasticity, and long-term memory (LTM). Drosophila Orb and Orb2 are single members of the CPEB1 and CPEB2 subfamilies of the CPEB proteins, respectively. At present, the identity of the mRNA targets they regulate is not fully known, and the binding specificity of the CPEB2 subfamily is a matter of debate. Using transcriptome-wide UV cross-linking and immunoprecipitation, we define the mRNA-binding sites and targets of Drosophila CPEBs. Both Orb and Orb2 bind linear cytoplasmic polyadenylation element-like sequences in the 3′ UTRs of largely overlapping target mRNAs, with Orb2 potentially having a broader specificity. Both proteins use their RNA-recognition motifs but not the Zinc-finger region for RNA binding. A subset of Orb2 targets is translationally regulated in cultured S2 cells and fly head extracts. Moreover, pan-neuronal RNAi knockdown of these targets suggests that a number of these targets are involved in LTM. Our results provide a comprehensive list of mRNA targets of the two CPEB proteins in Drosophila, thus providing insights into local protein synthesis involved in various biological processes, including LTM.

Project description:Background: The vertebrate CPEB-family of RNA-binding proteins promote translational repression or activation of their target mRNAs, which harbor cytoplasmic polyadenylation elements (CPEs) in their 3’ UTRs, through cytoplasmic changes in their poly(A) tail lengths. However, their regulation(s) and mechanism(s) of action have not been systematically addressed as a family. Results: Here we perform a comparative analysis of the four vertebrate CPEBs in their regulation by phosphorylation, supramolecular assemblies’ composition and properties and in their mRNA targets. Conclusions: We show that although all four CPEBs are able to recruit CCR4-NOT deadenylation complex when not phosphorylated, their mechanisms of action determine two subfamilies with distinct, but coordinated, regulation by phosphorylation and target specificity. Thus, CPEB1 forms ribonucleoprotein complexes that are remodeled upon a single phosphorylation event, by AurkA, and are associated with mRNAs containing canonical CPEs. On the other hand, CPEB2-4 are regulated by multiple proline-directed phosphorylations that control their liquid-liquid phase-separation. CPEB2-4 mRNA-targets include CPEB1-bound transcripts, with canonical CPEs, but also a specific subset of mRNAs with non-canonical CPEs. In turn, CPEB2-4 coacervates display compositional, morphological and dynamic differences. Altogether, these results show how, globally, the CPEB family of proteins is able to integrate cellular cues to generate a finetuned adaptive response in gene expression regulation.

Project description:Background: The vertebrate CPEB-family of RNA-binding proteins promote translational repression or activation of their target mRNAs, which harbor cytoplasmic polyadenylation elements (CPEs) in their 3’ UTRs, through cytoplasmic changes in their poly(A) tail lengths. However, their regulation(s) and mechanism(s) of action have not been systematically addressed as a family. Results: Here we perform a comparative analysis of the four vertebrate CPEBs in their regulation by phosphorylation, supramolecular assemblies’ composition and properties and in their mRNA targets. Conclusions: We show that although all four CPEBs are able to recruit CCR4-NOT deadenylation complex when not phosphorylated, their mechanisms of action determine two subfamilies with distinct, but coordinated, regulation by phosphorylation and target specificity. Thus, CPEB1 forms ribonucleoprotein complexes that are remodeled upon a single phosphorylation event, by AurkA, and are associated with mRNAs containing canonical CPEs. On the other hand, CPEB2-4 are regulated by multiple proline-directed phosphorylations that control their liquid-liquid phase-separation. CPEB2-4 mRNA-targets include CPEB1-bound transcripts, with canonical CPEs, but also a specific subset of mRNAs with non-canonical CPEs. In turn, CPEB2-4 coacervates display compositional, morphological and dynamic differences. Altogether, these results show how, globally, the CPEB family of proteins is able to integrate cellular cues to generate a finetuned adaptive response in gene expression regulation.

Project description:Background: The vertebrate CPEB-family of RNA-binding proteins promote translational repression or activation of their target mRNAs, which harbor cytoplasmic polyadenylation elements (CPEs) in their 3’ UTRs, through cytoplasmic changes in their poly(A) tail lengths. However, their regulation(s) and mechanism(s) of action have not been systematically addressed as a family. Results: Here we perform a comparative analysis of the four vertebrate CPEBs in their regulation by phosphorylation, supramolecular assemblies’ composition and properties and in their mRNA targets. Conclusions: We show that although all four CPEBs are able to recruit CCR4-NOT deadenylation complex when not phosphorylated, their mechanisms of action determine two subfamilies with distinct, but coordinated, regulation by phosphorylation and target specificity. Thus, CPEB1 forms ribonucleoprotein complexes that are remodeled upon a single phosphorylation event, by AurkA, and are associated with mRNAs containing canonical CPEs. On the other hand, CPEB2-4 are regulated by multiple proline-directed phosphorylations that control their liquid-liquid phase-separation. CPEB2-4 mRNA-targets include CPEB1-bound transcripts, with canonical CPEs, but also a specific subset of mRNAs with non-canonical CPEs. In turn, CPEB2-4 coacervates display compositional, morphological and dynamic differences. Altogether, these results show how, globally, the CPEB family of proteins is able to integrate cellular cues to generate a finetuned adaptive response in gene expression regulation.

Project description:Analysis of mRNA changes in HeLa cells following Ago2 or Dicer depletion. Dicer, a cytoplasmic RNase III, generates the mature form of small RNAs including microRNA. Ago2 is a component of an effector complex of microRNA. Keywords: gene expression array-based (RNA / in situ oligonucleotide)

Project description:Metazoan gamete development into sperm or oocytes requires specific programming cues. Many of these cues function through conserved proteins to regulate gene expression. In C. elegans, two proteins are the terminal regulators of the genetic regulatory network controlling sperm fate: FOG-1, a cytoplasmic polyadenylation element binding protein (CPEB), and FOG-3, a predicted Tob/BTG protein. Loss of either gene causes hermaphrodites or male germ cells to switch from making sperm to making oocytes. Characterized Tob/BTG proteins function as adaptor proteins, linking – in certain contexts – deadenylases to mRNA via CPEB RNA motifs. Through crosslinking and sequencing, we confirmed FOG-3 binds to RNA directly and observed a preference for mRNA 3’UTRs. Our results bring together prior genetics and molecular biology data to propose a new molecular function in germ cell specification with a Tob protein. We discuss the potential for FOG-3 to function as an mRNA packaging protein to inhibit target genes, as well as the potential for the existence of other hidden protein polymers in biology.