Purification and characterization of the Upf1 protein: a factor involved in translation and mRNA degradation.

mRNA degradation is an important control point in the regulation of gene expression and has been shown to be linked to the process of translation. One clear example of this linkage is the observation that nonsense mutations in a gene can accelerate the decay of the corresponding mRNA. In the yeast Saccharomyces cerevisiae, the product of the UPF1 gene, harboring zinc finger, NTP hydrolysis, and helicase motifs, was shown to be a trans-acting factor in this decay pathway. A UPF1 gene disruption results in stabilization of nonsense-containing mRNAs and leads to a nonsense suppression phenotype. As a first step toward understanding the molecular and biochemical mechanism of nonsense-mediated mRNA decay, we have purified Upf1p from a yeast extract and characterized its nucleic acid-dependent NTPase activity, helicase activity, and nucleic acid binding properties. The results presented in this paper demonstrate that Upf1p contains both RNA- and DNA-dependent ATPase activities and RNA and DNA helicase activities. In the absence of ATP, Upf1p binds to single-stranded RNA or DNA, whereas hydrolysis of ATP facilitates its release from single-stranded nucleic acid. Based on these results, the role of Upf1p's biochemical activities in mRNA decay and translation are discussed.     

Upf1p, Nmd2p, and Upf3p are interacting components of the yeast nonsense-mediated mRNA decay pathway.

Rapid turnover of nonsense-containing mRNAs in Saccharomyces cerevisiae is dependent on Upf1p, Nmd2p, and Upf3p, the products of the UPF1, NMD2/UPF2, and UPF3 genes, respectively. We showed previously that Upf1p and Nmd2p interact and that this interaction is required for nonsense-mediated mRNA decay (F. He and A. Jacobson, Genes Dev. 9:437-454, 1995; F. He, A. H. Brown, and A. Jacobson, RNA 2:153-170, 1996). In this study we have used the yeast two-hybrid system to define other protein-protein interactions among the essential components of this decay pathway. Nmd2p-Upf3p and Upf1p-Upf3p interactions were identified, and the respective domains involved in these interactions were delineated by deletion analysis. The domains of Upf1p and Upf3p putatively involved in their mutual interaction were found to correspond to the domains on the two proteins which interact with Nmd2p, suggesting that Nmd2p bridges Upf1p and Upf3p. This conclusion was reinforced by experiments showing that: (i) deletion of NMD2 completely abolishes interactions between Upf1p and Upf3p and (ii) overexpression of full-length Nmd2p or Nmd2p fragments that retain Upf1p- and Upf3p-interacting domains promotes 10- to 200-fold enhancement of Upf1p-Nmd2p-Upf3p complex formation. These results; the observation that cells harboring either single or multiple deletions of UPF1, NMD2, and UPF3 inhibit nonsense-mediated mRNA decay to the same extent; and an analysis of the possible targets of a dominant-negative NMD2 allele indicate that Upf1p, Nmd2p, Upf3p, and at least one other factor are functionally dependent, interacting components of the yeast nonsense-mediated mRNA decay pathway.     

TOR controls translation initiation and early G1 progression in yeast.

Saccharomyces cerevisiae cells treated with the immunosuppressant rapamycin or depleted for the targets of rapamycin TOR1 and TOR2 arrest growth in the early G1 phase of the cell cycle. Loss of TOR function also causes an early inhibition of translation initiation and induces several other physiological changes characteristic of starved cells entering stationary phase (G0). A G1 cyclin mRNA whose translational control is altered by substitution of the UBI4 5' leader region (UBI4 is normally translated under starvation conditions) suppresses the rapamycin-induced G1 arrest and confers starvation sensitivity. These results suggest that the block in translation initiation is a direct consequence of loss of TOR function and the cause of the G1 arrest. We propose that the TORs, two related phosphatidylinositol kinase homologues, are part of a novel signaling pathway that activates eIF-4E-dependent protein synthesis and, thereby, G1 progression in response to nutrient availability. Such a pathway may constitute a checkpoint that prevents early G1 progression and growth in the absence of nutrients.     

The yeast nuclear cap binding complex can interact with translation factor eIF4G and mediate translation initiation

The mRNA cap structure is bound by either the nuclear (CBC) or the cytoplasmic (eIF4F) cap binding complex. Following mRNA export, CBC must be exchanged for eIF4F in the cytoplasm. It is not known how this exchange occurs or how this RNP remodeling event is integrated with mRNA function. Here we report genetic and biochemical evidence that the yeast translation initiation factor eIF4G associates with CBC, and that eIF4E, the eIF4F component that binds both the cap and eIF4G, antagonizes this interaction. Furthermore, we find that CBC can stimulate translation in extracts containing an eIF4G protein deficient for eIF4E binding. These data suggest that eIF4E binding to the eIF4G-CBC complex on newly exported mRNA displaces CBC, and that the first round of translation on mRNA may occur via a different mechanism than subsequent rounds.     

Human Upf proteins target an mRNA for nonsense-mediated decay when bound downstream of a termination codon

Nonsense-mediated decay (NMD) rids eukaryotic cells of aberrant mRNAs containing premature termination codons. These are discriminated from true termination codons by downstream cis-elements, such as exon-exon junctions. We describe three novel human proteins involved in NMD, hUpf2, hUpf3a, and hUpf3b. While in HeLa cell extracts these proteins are complexed with hUpf1, in intact cells hUpf3a and hUpf3b are nucleocytoplasmic shuttling proteins, hUpf2 is perinuclear, and hUpf1 cytoplasmic. hUpf3a and hUpf3b associate selectively with spliced beta-globin mRNA in vivo, and tethering of any hUpf protein to the 3'UTR of beta-globin mRNA elicits NMD. These data suggest that assembly of a dynamic hUpf complex initiates in the nucleus at mRNA exon-exon junctions and triggers NMD in the cytoplasm when recognized downstream of a translation termination site.     

Dengue virus utilizes a novel strategy for translation initiation when cap-dependent translation is inhibited

Viruses have developed numerous mechanisms to usurp the host cell translation apparatus. Dengue virus (DEN) and other flaviviruses, such as West Nile and yellow fever viruses, contain a 5' m7GpppN-capped positive-sense RNA genome with a nonpolyadenylated 3' untranslated region (UTR) that has been presumed to undergo translation in a cap-dependent manner. However, the means by which the DEN genome is translated effectively in the presence of capped, polyadenylated cellular mRNAs is unknown. This report demonstrates that DEN replication and translation are not affected under conditions that inhibit cap-dependent translation by targeting the cap-binding protein eukaryotic initiation factor 4E, a key regulator of cellular translation. We further show that under cellular conditions in which translation factors are limiting, DEN can alternate between canonical cap-dependent translation initiation and a noncanonical mechanism that appears not to require a functional m7G cap. This DEN noncanonical translation is not mediated by an internal ribosome entry site but requires the interaction of the DEN 5' and 3' UTRs for activity, suggesting a novel strategy for translation of animal viruses.     

Interaction between Nmd2p and Upf1p is required for activity but not for dominant-negative inhibition of the nonsense-mediated mRNA decay pathway in yeast.

Rapid turnover of nonsense-containing mRNAs in the yeast Saccharomyces cerevisiae is dependent on the products of the UPF1 (Upf1p), NMD2/UPF2 (Nmd2p) and UPF3 (Upf3p) genes. Mutations in each of these genes lead to the selective stabilization of mRNAs containing early nonsense mutations without affecting the decay rates of most other mRNAs. NMD2 was recently identified in a two-hybrid screen as a gene that encodes a Upf1p-interacting protein. To identify the amino acids essential to this interaction, we used two-hybrid analysis as well as missense, nonsense, and deletion mutants of NMD2, and mapped the Upf1p-interacting domain of Nmd2p to a 157-amino acid segment at its C-terminus. Mutations in this domain that disrupt interaction with Upf1p also disrupt nonsense-mediated mRNA decay. A dominant-negative deletion allele of NMD2 identified previously includes the Upf1p-interacting domain. However, mutations in the Upf1p-interacting domain do not affect dominant-negative inhibition of mRNA decay caused by this allele, suggesting interaction with yet another factor. These results, and the observation that deletion of a putative nuclear localization signal and a putative transmembrane domain also inactivate nonsense-mediated mRNA decay, suggest that Nmd2p may contain as many as four important functional domains.     

CBP80 promotes interaction of Upf1 with Upf2 during nonsense-mediated mRNA decay in mammalian cells

In mammalian cells, nonsense-mediated messenger RNA decay (NMD) targets newly synthesized nonsense-containing mRNA bound by the cap-binding-protein heterodimer CBP80-CBP20 and at least one exon-junction complex (EJC). An EJC includes the NMD factors Upf3 or Upf3X and Upf2, and Upf2 recruits Upf1. Once this pioneer translation initiation complex is remodeled so that CBP80-CBP20 is replaced by eukaryotic initiation factor 4E, the mRNA is no longer detectably targeted for NMD. Here, we provide evidence that CBP80 augments the efficiency of NMD but not of Staufen1 (Stau1)-mediated mRNA decay (SMD). SMD depends on the recruitment of Upf1 by the RNA-binding protein Stau1 but does not depend on the other Upf proteins. We find that CBP80 interacts with Upf1 and promotes the interaction of Upf1 with Upf2 but not with Stau1.     

Phosphorylation and N-terminal region of yeast ribosomal protein P1 mediate its degradation, which is prevented by protein P2

The stalk proteins P1 and P2, which are fundamental for ribosome activity, are the only ribosomal components for which there is a cytoplasmic pool. Accumulation of these two proteins is differentially regulated in Saccharomyces cerevisiae by degradation. In the absence of P2, the amount of P1 is drastically reduced; in contrast, P2 proteins are not affected by a deficiency in P1. However, association with P2 protects P1 proteins. The half-life of P1 is a few minutes, while that of P2 is several hours. The proteasome is not involved in the degradation of P1 proteins. The different sensitivity to degradation of these two proteins is associated with two structural features: phosphorylation and N-terminus structure. A phosphorylation site at the C-terminus is required for P1 proteolysis. P2 proteins, despite being phosphorylated, are protected by their N-terminal peptide. An exchange of the first five amino acids between the two types of protein makes P1 resistant and P2 sensitive to degradation.     

ATP is a cofactor of the Upf1 protein that modulates its translation termination and RNA binding activities.

The nonsense-mediated mRNA decay pathway decreases the abundance of mRNAs that contain premature termination codons and prevents suppression of nonsense alleles. The UPF1 gene in the yeast Saccharomyces cerevisiae was shown to be a trans-acting factor in this decay pathway. The Upf1p demonstrates RNA-dependent ATPase, RNA helicase, and RNA binding activities. The results presented here investigate the binding affinity of the Upf1p for ATP and the consequences of ATP binding on its affinity for RNA. The results demonstrate that the Upf1p binds ATP in the absence of RNA. Consistent with this result, the TR800AA mutant form of the Upf1p still bound ATP, although it does not bind RNA. ATP binding also modulates the affinity of Upf1p for RNA. The RNA binding activity of the DE572AA mutant form of the Upf1p, which lacks ATPase activity, still bound ATP as efficiently as the wild-type Upf1p and destabilized the Upf1p-RNA complex. Similarly, ATPgammaS, a nonhydrolyzable analogue of ATP, interacted with Upf1p and promoted disassociation of the Upf1p-RNA complex. The conserved lysine residue (K436) in the helicase motif Ia in the Upf1p was shown to be critical for ATP binding. Taken together, these findings formally prove that ATP can bind Upf1p in the absence of RNA and that this interaction has consequences on the formation of the Upf1p-RNA complex. Further, the results support the genetic evidence indicating that ATP binding is important for the Upf1p to increase the translation termination efficiency at a nonsense codon. Based on these findings, a model describing how the Upf1p functions in modulating translation and turnover and the potential insights into the mechanism of the Upf1p helicase will be discussed.     

Premature translation termination mediates triosephosphate isomerase mRNA degradation.

We characterized an anemia-inducing mutation in the human gene for triosephosphate isomerase (TPI) that resulted in the production of prematurely terminated protein and mRNA with a reduced cytoplasmic half-life. The mutation converted a CGA arginine codon to a TGA nonsense codon and generated a protein of 188 amino acids, instead of the usual 248 amino acids. To determine how mRNA primary structure and translation influence mRNA stability, in vitro-mutagenized TPI alleles were introduced into cultured L cells and analyzed for their effect on TPI RNA metabolism. Results indicated that mRNA stability is decreased by all nonsense and frameshift mutations. To determine the relative contribution of the changes in mRNA structure and translation to the altered half-life, the effects of individual mutations were compared with the effects of second-site reversions that restored translation termination to normal. All mutations that resulted in premature translation termination reduced the mRNA half-life solely or mainly by altering the length of the mRNA that was translated. The only mutation that altered translation termination and that reduced the mRNA half-life mainly by affecting the mRNA structure was an insertion that shifted termination to a position downstream of the normal stop codon.     

Rps5-Rps16 communication is essential for efficient translation initiation in yeast S. cerevisiae

Conserved ribosomal proteins frequently harbor additional segments in eukaryotes not found in bacteria, which could facilitate eukaryotic-specific reactions in the initiation phase of protein synthesis. Here we provide evidence showing that truncation of the N-terminal domain (NTD) of yeast Rps5 (absent in bacterial ortholog S7) impairs translation initiation, cell growth and induction of GCN4 mRNA translation in a manner suggesting incomplete assembly of 48S preinitiation complexes (PICs) at upstream AUG codons in GCN4 mRNA. Rps5 mutations evoke accumulation of factors on native 40S subunits normally released on conversion of 48S PICs to 80S initiation complexes (ICs) and this abnormality and related phenotypes are mitigated by the SUI5 variant of eIF5. Remarkably, similar effects are observed by substitution of Lys45 in the Rps5-NTD, involved in contact with Rps16, and by eliminating the last two residues of the C-terminal tail (CTT) of Rps16, believed to contact initiator tRNA base-paired to AUG in the P site. We propose that Rps5-NTD-Rps16-NTD interaction modulates Rps16-CTT association with Met-tRNA_i^Met to promote a functional 48S PIC.