Structural and Biochemical Insights to the Role of the CCR4-NOT Complex and DDX6 ATPase in MicroRNA Repression

Mathys, Hansruedi; Basquin, J.; Ozgur, Sevim; Czarnocki-Cieciura, Mariusz; Bonneau, Fabien; Aartse, Aafke; Dziembowski, Andrzej; Nowotny, Marcin; Conti, Elena; Filipowicz, Witold

doi:10.1016/j.molcel.2014.03.036

Cited by 270 publications

(459 citation statements)

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“…We and others have shown that DDX6 acts downstream of the CCR4–NOT complex to mediate translational repression and stimulate decapping in human cells (Chen et al , 2014; Mathys et al , 2014; Rouya et al , 2014). To further confirm that DDX6 function lies downstream of CCR4–NOT, we used tethering assays to analyze the repressive activity of a NOT1 mutant that it is impaired in binding to DDX6 but binds to CNOT2 and CNOT3 (Fig 6G, NOT1 Mut; Appendix Table S1).…”

Section: Resultsmentioning

confidence: 95%

“…One possible model is that the recruitment of the CCR4–NOT complex is sufficient to mediate silencing (Jonas & Izaurralde, 2015). This model is based on the following observations: First, the interaction of GW182 proteins with the CCR4–NOT complex is not only required for degradation but also required for translational repression of miRNA reporters (Braun et al , 2011; Chekulaeva et al , 2011; Fabian et al , 2011; Huntzinger et al , 2013; Zekri et al , 2013; Chen et al , 2014; Mathys et al , 2014). Second, like miRISC, the CCR4–NOT complex represses translation in the absence of deadenylation (Cooke et al , 2010; Braun et al , 2011; Chekulaeva et al , 2011; Bawankar et al , 2013; Zekri et al , 2013).…”

Section: Introductionmentioning

confidence: 99%

“…Translational repression by the CCR4–NOT complex can, at least in part, be explained by a direct interaction between the NOT1 subunit and the DEAD‐box ATPase DDX6 (also known as RCK). Human DDX6 and its Drosophila melanogaster ( Dm ) ortholog Me31B repress translation, activate decapping, and play a role in silencing (Chu & Rana, 2006; Eulalio et al , 2007; Nishihara et al , 2013; Chen et al , 2014; Mathys et al , 2014; Rouya et al , 2014). …”

Section: Introductionmentioning

confidence: 99%

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mi RISC and the CCR 4– NOT complex silence mRNA targets independently of 43S ribosomal scanning

et al. 2016

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AbstractmiRNAs associate with Argonaute (AGO) proteins to silence the expression of mRNA targets by inhibiting translation and promoting deadenylation, decapping, and mRNA degradation. A current model for silencing suggests that AGOs mediate these effects through the sequential recruitment of GW182 proteins, the CCR4–NOT deadenylase complex and the translational repressor and decapping activator DDX6. An alternative model posits that AGOs repress translation by interfering with eIF4A function during 43S ribosomal scanning and that this mechanism is independent of GW182 and the CCR4–NOT complex in Drosophila melanogaster. Here, we show that miRNAs, AGOs, GW182, the CCR4–NOT complex, and DDX6/Me31B repress and degrade polyadenylated mRNA targets that are translated via scanning‐independent mechanisms in both human and Dm cells. This and additional observations indicate a common mechanism used by these proteins and miRNAs to mediate silencing. This mechanism does not require eIF4A function during ribosomal scanning.

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Section: Resultsmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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mi RISC and the CCR 4– NOT complex silence mRNA targets independently of 43S ribosomal scanning

et al. 2016

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“…2b). In addition, CCR4-NOT interacts via its CNOT1 subunit with the DEAD-box helicase DDX6 which functions as a translational repressor and activator of decapping [102,103] (Fig 2c) Piwis: After primary biogenesis, piRNA loaded RNA-induced silencing complexes (piRISCs) are loaded with 26-31 nt guides that are not only typically longer than si-or miRNAs, but are also 2′-O-methylated at their 3′ end. Our current understanding of the molecular mechanisms of Piwi proteins is primarily based on numerous genetic screens, biochemical assays, and comparisons to their Ago counterparts.…”

Section: Hhmi Author Manuscriptmentioning

confidence: 99%

“…2b). In addition, CCR4-NOT interacts via its CNOT1 subunit with the DEAD-box helicase DDX6 which functions as a translational repressor and activator of decapping [102,103] (Fig 2c) (Box 2). Finally, post-translational modification of Argonautes by numerous factors can also affect silencing activity by influencing small RNA binding or protein stability (reviewed in [104]), thus adding another layer of regulation, particularly to miRNA silencing.…”

Section: Rnai Effector Machinerymentioning

confidence: 99%

From guide to target: molecular insights into eukaryotic RNA-interference machinery

Ipsaro

Joshua‐Tor

2015

Nat Struct Mol Biol

210

144

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Since its relatively recent discovery, RNA interference (RNAi) has emerged as a potent, specific, and ubiquitous means of gene regulation. Through a number of pathways that are conserved from yeast to humans, small non-coding RNAs direct molecular machinery to silence gene expression. In this review, we focus on mechanisms and structures that govern RNA silencing in higher organisms. In addition to highlighting recent advances, parallels and differences between RNAi pathways are discussed. Together, the studies reviewed herein reveal the versatility and programmability of RNA-induced Silencing Complexes (RISCs) and emphasize the importance of both upstream biogenesis and downstream silencing factors. Discovery and Biological Perspectives of RNA interferenceRNAi was first described by Fire and Mello in the 1990s when, in an attempt to use antisense RNA to down-regulate gene expression, they observed that double-stranded RNA (dsRNA) was more potent than sense or anti-sense RNA alone [1]. This seminal work boasted robust and specific gene knock down in addition to coining the term "RNA interference" (RNAi). Shortly beforehand, the discovery of individual regulatory RNAs in C. elegans hinted that small, non-coding RNAs might be a pervasive means of gene regulation in higher organisms [2,3]. In the following decade, with the mechanistic insight of Fire and Mello's work in hand, this idea was confirmed and it is now accepted that wellover 1,000 small RNAs are encoded in the human genome that may regulate over 60% of our genes [4,5]. It also became apparent that several seemingly disconnected phenomena are variations of RNAi-type pathways including co-suppression in plants, DNA elimination in Tetrahymena, and quelling in Neurospora [6]. The prevalence of RNAi is impressive and its importance is underscored by the fact that RNAi dysfunction is associated with numerous diseases and disorders including neurological maladies, cancers, and infertility.Shortly after the initial description of RNAi phenomenology, a burst of genetic, biochemical, biophysical, and bioinformatic efforts laid a strong foundation for identifying the molecular pathways, players, and parameters that govern silencing via RNAi. Work from Reprints and permissions information is available online at http://www.nature.com/reprints/index.html. HHMI Author ManuscriptHHMI Author Manuscript HHMI Author Manuscript numerous groups defined the molecular apparatus of RNAi as RISC (RNA-induced Silencing Complex), a ribonucleoprotein complex minimally comprised of a small singlestranded RNA (~20-31 nucleotides) and an Argonaute protein which serves as the effector molecule (reviewed in [7]). In this configuration, the loaded "guide" RNA acts as a specificity determinant that directs Argonaute and any other associated machinery to the target. The guide-loaded Argonaute platform underlies every example in the expansive array of known RNAi pathways in eukaryotes regardless of the source of the guide (structured loci, transposons, viral, etc.), the machinery ...

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1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg²⁺‐dependent binding

et al. 2019

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In eukaryotic cells, cytoplasmic mRNA is characterised by a 3′ poly(A) tail. The shortening and removal of poly(A) tails (deadenylation) by the Ccr4‐Not nuclease complex leads to reduced translational efficiency and RNA degradation. Using recombinant human Caf1 (CNOT7) enzyme as a screening tool, we recently described the discovery and synthesis of a series of substituted 1‐hydroxy‐3,7‐dihydro‐1H‐purine‐2,6‐diones (1‐hydroxy‐xanthines) as inhibitors of the Caf1 catalytic subunit of the Ccr4‐Not complex. Here, we used a chemiluminescence‐based AMP detection assay to show that active 1‐hydroxy‐xanthines inhibit both isolated Caf1 enzyme and human Caf1‐containing complexes that also contain the second nuclease subunit Ccr4 (CNOT6L) to a similar extent, indicating that the active site of the Caf1 nuclease subunit does not undergo substantial conformational change when bound to other Ccr4‐Not subunits. Using differential scanning fluorimetry, we also show that binding of active 1‐hydroxy‐xanthines requires the presence of Mg2+ ions, which are present in the active site of Caf1.

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Structural and Biochemical Insights to the Role of the CCR4-NOT Complex and DDX6 ATPase in MicroRNA Repression

Cited by 270 publications

References 51 publications

mi RISC and the CCR 4– NOT complex silence mRNA targets independently of 43S ribosomal scanning

mi RISC and the CCR 4– NOT complex silence mRNA targets independently of 43S ribosomal scanning

From guide to target: molecular insights into eukaryotic RNA-interference machinery

1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg²⁺‐dependent binding

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Structural and Biochemical Insights to the Role of the CCR4-NOT Complex and DDX6 ATPase in MicroRNA Repression

Cited by 270 publications

References 51 publications

mi RISC and the CCR 4– NOT complex silence mRNA targets independently of 43S ribosomal scanning

mi RISC and the CCR 4– NOT complex silence mRNA targets independently of 43S ribosomal scanning

From guide to target: molecular insights into eukaryotic RNA-interference machinery

1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg2+‐dependent binding

Contact Info

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1‐Hydroxy‐xanthine derivatives inhibit the human Caf1 nuclease and Caf1‐containing nuclease complexes via Mg²⁺‐dependent binding