Poly(A)-binding proteins regulate both mRNA deadenylation and decapping in yeast cytoplasmic extracts.

The pathway of mRNA degradation has been extensively studied in the yeast, Saccharomyces cerevisiae, and it is now clear that many mRNAs decay by a deadenylation-dependent mechanism. Although several of the factors required for mRNA decay have been identified, the regulation and precise roles of many of the proteins involved remains unclear. We have developed an in vitro system that recapitulates both the deadenylation and the decapping steps of mRNA decay. Furthermore, both deadenylation and decapping are inhibited by poly(A) binding proteins in our assay. Our system has allowed us to separate the decay process from translation and we have shown that the poly(A) tail is capable of inhibiting decapping in an eIF4E-independent manner. Our in vitro system should prove invaluable in dissecting the mechanisms of mRNA turnover.

Nonsense-mediated mRNA decay in Saccharomyces cerevisiae.

Cell survival depends on the precise and correct production of polypeptides. Eukaryotic cells have evolved conserved proofreading mechanisms to get rid of incomplete and potentially deleterious proteins. The nonsense-mediated mRNA decay (NMD) pathway is an example of a surveillance mechanism that monitors premature translation termination and promotes degradation of aberrant transcripts that code for nonfunctional or even harmful proteins. In this review we will describe our current knowledge of the NMD pathway, analyzing primarily the results obtained from the yeast Saccharomyces cerevisiae, but establishing functional comparisons with those obtained in higher eukaryotes. Based on these observations, we present two related working models to explain how this surveillance pathway recognizes and selectively degrades aberrant mRNAs.

Regulated ARE-mediated mRNA decay in Saccharomyces cerevisiae.

The stability of several oncogene, cytokine, and growth factor transcripts is tightly regulated by signaling pathways through an ARE (AU-rich element) present in their 3'-UTRs. We have identified a yeast transcript, TIF51A, whose stability is regulated through its AU-rich 3'-UTR. We demonstrate that the mammalian TNFalpha and c-fos AREs regulate turnover of a reporter yeast transcript in a similar manner. AREs stabilize the transcript in glucose media and function as destabilizing elements in media lacking glucose or when the Hog1p/p38 MAP kinase pathway is inhibited. Significantly, both yeast and mammalian AREs promote deadenylation-dependent decapping in the yeast system. Furthermore, the yeast ELAV homolog, Pub1p, regulates the stability mediated by the TNFalpha ARE. These results demonstrate that yeast possess a regulatable mechanism for ARE-mediated decay and suggest conservation of this turnover process from yeast to humans.

Characterization of a general stabilizer element that blocks deadenylation-dependent mRNA decay.

mRNA degradation is a regulated process that can play an important role in determining the level of expression of specific genes. The rate at which a specific mRNA is degraded depends largely on specific cis-acting sequences located throughout the transcript. cis-Acting destabilizer sequences that promote increased rates of decay have been identified in several short-lived mRNAs. However, little is known about elements that promote stability, known as stabilizer elements (STEs), and how they function. The work presented here describes the characterization of a STE in the PGK1 transcript. The PGK1 stabilizer element (P-STE) has been delineated to a 64-nucleotide sequence from the coding region that can stabilize a chimeric transcript containing the instability elements from the 3'-untranslated region of the MFA2 transcript. The P-STE is located within the PGK1 coding region and functions when located in the translated portion of the transcript and at a minimum distance from the 3'-untranslated region. These results further support the link between translation and mRNA degradation. A conserved sequence in the TEF1/2 transcript has been identified that also functions as a STE, suggesting that this sequence element maybe a general stability determinant found in other yeast mRNAs.

The cap-to-tail guide to mRNA turnover.

The levels of cellular messenger RNA transcripts can be regulated by controlling the rate at which the mRNA decays. Because decay rates affect the expression of specific genes, they provide a cell with flexibility in effecting rapid change. Moreover, many clinically relevant mRNAs--including several encoding cytokines, growth factors and proto-oncogenes--are regulated by differential RNA stability. But what are the sequence elements and factors that control the half-lives of mRNAs?

A novel mRNA-decapping activity in HeLa cytoplasmic extracts is regulated by AU-rich elements.

While decapping plays a major role in mRNA turnover in yeast, biochemical evidence for a similar activity in mammalian cells has been elusive. We have now identified a decapping activity in HeLa cytoplasmic extracts that releases (7me)GDP from capped transcripts. Decapping is activated in extracts by the addition of (7me)GpppG, which specifically sequesters cap-binding proteins such as eIF4E and the deadenylase DAN/PARN. Similar to in vivo observations, the presence of a poly(A) tail represses decapping of RNAs in vitro in a poly(A)-binding protein-dependent fashion. AU-rich elements (AREs), which act as regulators of mRNA stability in vivo, are potent stimulators of decapping in vitro. The stimulation of decapping by AREs requires sequence-specific ARE-binding proteins. These data suggest that cap recognition and decapping play key roles in mediating mRNA turnover in mammalian cells.

The role of Upf proteins in modulating the translation read-through of nonsense-containing transcripts.

The yeast UPF1, UPF2 and UPF3 genes encode trans-acting factors of the nonsense-mediated mRNA decay pathway. In addition, the upf1Delta strain demonstrates a nonsense suppression phenotype and Upf1p has been shown to interact with the release factors eRF1 and eRF3. In this report, we show that both upf2Delta and upf3Delta strains demonstrate a nonsense suppression phenotype independent of their effect on mRNA turnover. We also demonstrate that Upf2p and Upf3p interact with eRF3, and that their ability to bind eRF3 correlates with their ability to complement the nonsense suppression phenotype. In vitro experiments demonstrate that Upf2p, Upf3p and eRF1 compete with each other for interacting with eRF3. Con versely, Upf1p binds to a different region of eRF3 and can form a complex with these factors. These results suggest a sequential surveillance complex assembly pathway, which occurs during the premature translation termination process. We propose that the observed nonsense suppression phenotype in the upfDelta strains can be attributed to a defect in the surveillance complex assembly.

Characterization of the biochemical properties of the human Upf1 gene product that is involved in nonsense-mediated mRNA decay.

The Upf1 protein in yeast has been implicated in the modulation of efficient translation termination as well as in the accelerated turnover of mRNAs containing premature stop codons, a phenomenon called nonsense-mediated mRNA decay (NMD). A human homolog of the yeast UPF1, termed HUpf1/RENT1, has also been identified. The HUpf1 has also been shown to play a role in NMD in mammalian cells. Comparison of the yeast and human UPF1 proteins demonstrated that the amino terminal cysteine/histidine-rich region and the region comprising the domains that define this protein as a superfamily group I helicase have been conserved. The yeast Upf1p demonstrates RNA-dependent ATPase and 5' --> 3' helicase activities. In this paper, we report the expression, purification, and characterization of the activities of the human Upf1 protein. We demonstrate that human Upf1 protein displays a nucleic-acid-dependent ATPase activity and a 5'--> 3' helicase activity. Furthermore, human Upf1 is an RNA-binding protein whose RNA-binding activity is modulated by ATP. Taken together, these results indicate that the activities of the Upf1 protein are conserved across species, reflecting the conservation of function of this protein throughout evolution.

The RNA binding protein Pub1 modulates the stability of transcripts containing upstream open reading frames.

The nonsense-mediated mRNA decay (NMD) pathway functions to degrade transcripts containing nonsense codons. Transcripts containing mutations that insert an upstream open reading frame (uORF) in the 5'-UTR are degraded through NMD. However, several naturally occurring uORF-containing transcripts are resistant to NMD. Here we demonstrate that the GCN4 and YAP1 mRNAs, which contain uORFs, harbor a stabilizer element (STE) that prevents rapid NMD by interacting with the RNA binding protein Pub1. Conversely, a uORF-containing mRNA that lacks an STE, such as CPA1, is degraded by the NMD pathway. These results indicate that uORFs can play a pivotal role regulating both translation and turnover and that the Pub1p is a critical factor that modulates the stability of uORF-containing transcripts.

The yeast hnRNP-like protein Hrp1/Nab4 marks a transcript for nonsense-mediated mRNA decay.

The nonsense-mediated mRNA decay (NMD) pathway monitors premature translation termination and degrades aberrant mRNAs. In yeast, it has been proposed that a surveillance complex searches 3' of a nonsense codon for a downstream sequence element (DSE) associated with RNA-binding proteins. An interaction between the complex and the DSE-binding protein(s) triggers NMD. Here we describe the identification and characterization of the Hrp1/Nab4 protein as a DSE-binding factor that activates NMD. Mutations in HRP1 stabilize nonsense-containing transcripts without affecting the decay of wild-type mRNAs. Hrp1p binds specifically to a DSE-containing RNA and interacts with Upf1p, a component of the surveillance complex. A mutation in HRP1 that stabilizes nonsense-containing mRNAs abolishes its affinity for the DSE and fails to interact with Upf1p. We present a model describing how Hrp1p marks a transcript for rapid decay.

Mtt1 is a Upf1-like helicase that interacts with the translation termination factors and whose overexpression can modulate termination efficiency.

Translation termination is the final step that completes the synthesis of a polypeptide. Premature translation termination by introduction of a nonsense mutation leads to the synthesis of a truncated protein. We report the identification and characterization of the product of the MTT1 gene, a helicase belonging to the Upfl-like family of helicases that is involved in modulating translation termination. MTT1 is homologous to UPF1, a factor previously shown to function in both mRNA turnover and translation termination. Overexpression of MTT1 induced a nonsense suppression phenotype in a wild-type yeast strain. Nonsense suppression is apparently not due to induction of [PSI+], even though cooverexpression of HSP104 alleviated the nonsense suppression phenotype observed in cells overexpressing MTT1, suggesting a more direct role of Hsp104p in the translation termination process. The MTT1 gene product was shown to interact with translation termination factors and is localized to polysomes. Taken together, these results indicate that at least two members of a family of RNA helicases modulate translation termination efficiency in cells.

Mutations in VPS16 and MRT1 stabilize mRNAs by activating an inhibitor of the decapping enzyme.

Decapping is a rate-limiting step in the decay of many yeast mRNAs; the activity of the decapping enzyme therefore plays a significant role in determining RNA stability. Using an in vitro decapping assay, we have identified a factor, Vps16p, that regulates the activity of the yeast decapping enzyme, Dcp1p. Mutations in the VPS16 gene result in a reduction of decapping activity in vitro and in the stabilization of both wild-type and nonsense-codon-containing mRNAs in vivo. The mrt1-3 allele, previously shown to affect the turnover of wild-type mRNAs, results in a similar in vitro phenotype. Extracts from both vps16 and mrt1 mutant strains inhibit the activity of purified Flag-Dcp1p. We have identified a 70-kDa protein which copurifies with Flag-Dcp1p as the abundant Hsp70 family member Ssa1p/2p. Intriguingly, the interaction with Ssa1p/2p is enhanced in strains with mutations in vps16 or mrt1. We propose that Hsp70s may be involved in the regulation of mRNA decapping.

Should we kill the messenger? The role of the surveillance complex in translation termination and mRNA turnover.

Eukaryotes have evolved conserved mechanisms to rid cells of faulty gene products that can interfere with cell function. mRNA surveillance is an example of a pathway that monitors the translation termination process and promotes degradation of transcripts harboring premature translation termination codons. Studies on the mechanism of mRNA surveillance in yeast and humans suggest a common mechanism where a "surveillance complex" monitors the translation process and determines whether translation termination has occurred at the correct position within the mRNA. A model will be presented that suggests that the surveillance complex assesses translation termination by monitoring the transition of an RNP as it is converted from a nuclear to a cytoplasmic form during the initial rounds of translation.

Mutations in the MOF2/SUI1 gene affect both translation and nonsense-mediated mRNA decay.

Recent studies have demonstrated that cells have evolved elaborate mechanisms to rid themselves of aberrant proteins and transcripts. The nonsense-mediated mRNA decay pathway (NMD) is an example of a pathway that eliminates aberrant mRNAs. In yeast, a transcript is recognized as aberrant and is rapidly degraded if a specific sequence, called the DSE, is present 3' of a premature termination codon. Results presented here show that strains harboring the mof2-1, mof4-1, mof5-1, and mof8-1 alleles, previously demonstrated to increase the efficiency of programmed -1 ribosomal frameshifting, decrease the activity of the NMD pathway. The effect of the mof2-1 allele on NMD was characterized in more detail. Previous results demonstrated that the wild-type MOF2 gene is identical to the SUI1 gene. Studies on the mof2-1 allele of the SUI1 gene indicate that in addition to its role in recognition of the AUG codon during translation initiation and maintenance of the appropriate reading frame during translation elongation, the Mof2 protein plays a role in the NMD pathway. The Mof2p/Sui1 p is conserved throughout nature and the human homolog of the Mof2p/Sui1p functions in yeast cells to activate NMD. These results suggest that factors involved in NMD are general modulators that act in several aspects of translation and mRNA turnover.

Cloning and characterization of a human genotoxic and endoplasmic reticulum stress-inducible cDNA that encodes translation initiation factor 1(eIF1(A121/SUI1)).

We report the cloning and characterization of a DNA damage-inducible (DDI) transcript DDI A121. The full-length human DDI A121 cDNA contains an open reading frame of 113 amino acids, corresponding to a protein of 12.7 kDa. The deduced amino acid sequence of A121 shows high homology to the yeast translation initiation factor (eIF) sui1 and also exhibits perfect identity to the partial sequence of recently purified human eIF1. Expression of human A121 corrected the mutant sui1 phenotype in yeast, demonstrating that human A121 encodes a bona fide translation initiation factor that is equivalent to yeast sui1p. The mammalian A121/SUI1 gene exhibits two transcripts (1.35 kilobases and 0.65 kilobases) containing a common coding region but differing in their 3'-untranslated region. The long and short A121/SUI1 mRNAs are differentially regulated by genotoxic and endoplasmic reticulum stress. The genotoxic stress induction of A121/SUI1 mRNA is conserved in both humans and rodents and occurs in a p53-independent manner. Our identification of a stress-inducible cDNA that encodes eIF1 suggests that modulation of translation initiation appears to occur during cellular stress and may represent an important adaptive response to genotoxic as well as endoplasmic reticulum stress.

Identification of putative programmed -1 ribosomal frameshift signals in large DNA databases.

The cis-acting elements that promote efficient ribosomal frameshifting in the -1 (5') direction have been well characterized in several viral systems. Results from many studies have convincingly demonstrated that the basic molecular mechanisms governing programmed -1 ribosomal frameshifting are almost identical from yeast to humans. We are interested in testing the hypothesis that programmed -1 ribosomal frameshifting can be used to control cellular gene expression. Toward this end, a computer program was designed to search large DNA databases for consensus -1 ribosomal frameshift signals. The results demonstrated that consensus programmed -1 ribosomal frameshift signals can be identified in a substantial number of chromosomally encoded mRNAs and that they occur with frequencies from two- to sixfold greater than random in all of the databases searched. A preliminary survey of the databases resulting from the computer searches found that consensus frameshift signals are present in at least 21 homologous genes from different species, 2 of which are nearly identical, suggesting evolutionary conservation of function. We show that four previously described missense alleles of genes that are linked to human diseases would disrupt putative programmed -1 ribosomal frameshift signals, suggesting that the frameshift signal may be involved in the normal expression of these genes. We also demonstrate that signals found in the yeast RAS1 and the human CCR5 genes were able to promote significant levels of programmed -1 ribosomal frameshifting. The significance of these frameshifting signals in controlling gene expression is not known, however.