Differential utilization of decapping enzymes in mammalian mRNA decay pathways

mRNA decapping is a crucial step in the regulation of mRNA stability and gene expression. Dcp2 is an mRNA decapping enzyme that has been widely studied. We recently reported the presence of a second mammalian cytoplasmic decapping enzyme, Nudt16. Here we address the differential utilization of the two decapping enzymes in specified mRNA decay processes. Using mouse embryonic fibroblast (MEF) cell lines derived from a hypomorphic knockout of the Dcp2 gene with undetectable levels of Dcp2 or MEF cell lines harboring a Nudt16-directed shRNA to generate reduced levels of Nudt16, we demonstrate the distinct roles for Dcp2 and Nudt16 in nonsense-mediated mRNA decay (NMD), decay of ARE-containing mRNA and miRNA-mediated silencing. Our results indicated that NMD preferentially utilizes Dcp2 rather than Nudt16; Dcp2 and Nudt16 are redundant in miRNA-mediated silencing; and Dcp2 and Nudt16 are differentially utilized for ARE-mRNA decay. These data demonstrate that the two distinct decapping enzymes can uniquely function in specific mRNA decay processes in mammalian cells.     

GW182 family proteins are crucial for microRNA-mediated gene silencing

microRNAs (miRNAs) are a conserved class of small RNAs approximately 22 nucleotides in length. They regulate the expression of a large number of mRNAs in animals and plants through the miRNA-induced silencing complex (miRISC). The conserved GW182 family of proteins has recently been identified, and its members have been shown to be associated with miRISC and to be required for miRNA-mediated gene silencing. These proteins have also been localized to processing bodies that are cytoplasmic messenger ribonucleoprotein (mRNP) aggregates containing mRNA decay factors, translational repressors and untranslated mRNAs. Therefore, these properties of GW182 family proteins support the hypothesis that the formation of untranslatable messenger ribonuclear protein particles is one important mechanism of miRNA-mediated gene silencing.     

RNA surveillance. Unforeseen consequences for gene expression, inherited genetic disorders and cancer

Messenger RNAs are monitored for errors that arise during gene expression by a mechanism called RNA surveillance, with the result that most mRNAs that cannot be translated along their full length are rapidly degraded. This ensures that truncated proteins are seldom made, reducing the accumulation of rogue proteins that might be deleterious. The pathway leading to accelerated mRNA decay is referred to as nonsense-mediated mRNA decay (NMD). The proteins that catalyze steps in NMD in yeast serve two roles, one to monitor errors in gene expression and the other to control the abundance of endogenous wild-type mRNAs as part of the normal repertoire of gene expression. The NMD pathway has a direct impact on hundreds of genetic disorders in the human population, where about a quarter of all known mutations are predicted to trigger NMD.     

Ago2/miRISC-mediated inhibition of CBP80/20-dependent translation and thereby abrogation of nonsense-mediated mRNA decay require the cap-associating activity of Ago2

Nuclear cap-binding protein (CBP) 80/20-dependent translation (CT) is one of the targets for miRNA-mediated gene silencing. Here, we provide evidence that human argonaute 2 (Ago2) competes with CBP80/20 for cap-association, inhibiting CT and thus nonsense-mediated mRNA decay (NMD), which is tightly coupled to CT. Tethering of Ago2, but not of Ago2F2V2 which lacks cap-association activity, to the 3'UTR of PTC-containing mRNA abrogates NMD. Immunoprecipitation using CBP80 antibody reveals that Ago2, but not Ago2F2V2, inhibits the binding of CBP80/20 to cap structure. Our observations provide molecular insight into the cross-talk between miRNA-mediated gene silencing, CT, and NMD.     

The RNA helicase Ddx5/p68 binds to hUpf3 and enhances NMD of Ddx17/p72 and Smg5 mRNA

Non-sense-mediated mRNA decay (NMD) is a mechanism of translation-dependent mRNA surveillance in eukaryotes: it degrades mRNAs with premature termination codons (PTCs) and contributes to cellular homeostasis by downregulating a number of physiologically important mRNAs. In the NMD pathway, Upf proteins, a set of conserved factors of which Upf1 is the central regulator, recruit decay enzymes to promote RNA cleavage. In mammals, the degradation of PTC-containing mRNAs is triggered by the exon–junction complex (EJC) through binding of its constituents Upf2 and Upf3 to Upf1. The complex formed eventually induces translational repression and recruitment of decay enzymes. Mechanisms by which physiological mRNAs are targeted by the NMD machinery in the absence of an EJC have been described but still are discussed controversially. Here, we report that the DEAD box proteins Ddx5/p68 and its paralog Ddx17/p72 also bind the Upf complex by physical interaction with Upf3, thereby interfering with the binding of EJC. By activating the NMD machinery, Ddx5 is shown to regulate the expression of its own, Ddx17 and Smg5 mRNAs. For NMD triggering, the adenosine triphosphate-binding activity of Ddx5 and the 3′-untranslated region of substrate mRNAs are essential.     

Nonsense-mediated mRNA decay: from vacuum cleaner to Swiss army knife

Nonsense-mediated mRNA decay (NMD) downmodulates mRNAs that have in-frame premature termination codons and prevents translation of potentially harmful truncated proteins from aberrant mRNAs. Two new approaches have identified physiological NMD substrates, and suggest that NMD functions as a multipurpose tool in the modulation of gene expression.     

mRNA surveillance of expressed pseudogenes in C. elegans

Messenger RNAs (mRNAs) that contain premature translation termination codons (PTCs) are targeted for rapid degradation in all eukaryotes tested. The mechanisms of nonsense-mediated mRNA decay (NMD) have been described in considerable detail, but the biological roles of NMD in wild-type organisms are poorly understood. mRNAs of wild-type organisms known to be degraded by NMD ("natural targets" of NMD) include by-products of regulated alternative splicing, out-of-frame mRNAs derived from unproductive gene rearrangements, cytoplasmic pre-mRNAs, endogenous retroviral and transposon RNAs, and mRNAs having upstream open reading frames or other unusual sequence features. NMD may function to eliminate aberrant PTC-containing mRNAs in order to protect cells from expression of potentially deleterious truncated proteins. Pseudogenes are nonfunctional genes or gene fragments that accumulate mutations through genetic drift. Such mutations will often introduce shifts of reading frame and/or PTCs, and mRNAs of expressed pseudogenes may thus be substrates of NMD. We demonstrate that mRNAs expressed from C. elegans pseudogenes are degraded by NMD and discuss possible implications for both mRNA surveillance and protein evolution. We describe an expressed pseudogene that encodes a small nucleolar RNA (snoRNA) within an intron and suggest this represents an evolutionary intermediate between snoRNA-encoding host genes that do or do not encode proteins.     

Applying nonsense-mediated mRNA decay research to the clinic: progress and challenges

Premature termination codons (PTCs) are equivalent to nonsense sequences. They encode no amino acid, and their presence precludes the synthesis of full-length proteins. Furthermore, the resulting truncated proteins, if synthesized and stable, are likely to be non-functional or might even be deleterious to cellular metabolism. Approximately one third of genetic and acquired diseases are due to PTCs. In fact, PTCs are apt to cause at least some cases of all diseases that involve protein insufficiency. Cells have evolved a way to eliminate mRNAs that contain PTCs using a mechanism called nonsense-mediated mRNA decay (NMD). Here, we will review how to determine which PTCs elicit NMD, what is currently known about the mechanism of NMD, and additional information that is pertinent to establishing therapies for PTC-associated diseases.