Your search keyword '"Eyler DE"' showing total 16 results

1. Expansion of base excision repair compensates for a lack of DNA repair by oxidative dealkylation in budding yeast

Author

Admiraal, SJ, Eyler, DE, Baldwin, MR, Brines, EM, Lohans, CT, Schofield, CJ, and O'Brien, PJ

Subjects

Alkylating Agents, Saccharomyces cerevisiae Proteins, Alkylation, DNA Repair, hydroxylase, Saccharomyces cerevisiae, DNA and Chromosomes, translation regulation, oxidative dealkylation, DNA Glycosylases, Substrate Specificity, Mag1, Escherichia coli, DNA, Fungal, Endodeoxyribonucleases, Methyl Methanesulfonate, Tpa1, base excision repair (BER), Oxidative Stress, Dealkylation, Mutation, Saccharomycetales, DNA damage, AlkB, AlkA, Carrier Proteins, Mutagens

Abstract

The Mag1 and Tpa1 proteins from budding yeast (Saccharomyces cerevisiae) have both been reported to repair alkylation damage in DNA. Mag1 initiates the base excision repair pathway by removing alkylated bases from DNA, and Tpa1 has been proposed to directly repair alkylated bases as does the prototypical oxidative dealkylase AlkB from Escherichia coli. However, we found that in vivo repair of methyl methanesulfonate (MMS)-induced alkylation damage in DNA involves Mag1 but not Tpa1. We observed that yeast strains without tpa1 are no more sensitive to MMS than WT yeast, whereas mag1-deficient yeast are ∼500-fold more sensitive to MMS. We therefore investigated the substrate specificity of Mag1 and found that it excises alkylated bases that are known AlkB substrates. In contrast, purified recombinant Tpa1 did not repair these alkylated DNA substrates, but it did exhibit the prolyl hydroxylase activity that has also been ascribed to it. A comparison of several of the kinetic parameters of Mag1 and its E. coli homolog AlkA revealed that Mag1 catalyzes base excision from known AlkB substrates with greater efficiency than does AlkA, consistent with an expanded role of yeast Mag1 in repair of alkylation damage. Our results challenge the proposal that Tpa1 directly functions in DNA repair and suggest that Mag1-initiated base excision repair compensates for the absence of oxidative dealkylation of alkylated nucleobases in budding yeast. This expanded role of Mag1, as compared with alkylation repair glycosylases in other organisms, could explain the extreme sensitivity of Mag1-deficient S. cerevisiae toward alkylation damage.

Published

2019

2. N1-Methylpseudouridine and pseudouridine modifications modulate mRNA decoding during translation.

Author

Monroe J, Eyler DE, Mitchell L, Deb I, Bojanowski A, Srinivas P, Dunham CM, Roy B, Frank AT, and Koutmou KS

Subjects

Humans, Ribosomes metabolism, Hydrogen Bonding, HEK293 Cells, Pseudouridine metabolism, Pseudouridine analogs & derivatives, RNA, Messenger metabolism, RNA, Messenger genetics, Protein Biosynthesis, Codon genetics, RNA, Transfer metabolism, RNA, Transfer genetics

Abstract

The ribosome utilizes hydrogen bonding between mRNA codons and aminoacyl-tRNAs to ensure rapid and accurate protein production. Chemical modification of mRNA nucleobases can adjust the strength and pattern of this hydrogen bonding to alter protein synthesis. We investigate how the N1-methylpseudouridine (m 1 Ψ) modification, commonly incorporated into therapeutic and vaccine mRNA sequences, influences the speed and fidelity of translation. We find that m 1 Ψ does not substantially change the rate constants for amino acid addition by cognate tRNAs or termination by release factors. However, we also find that m 1 Ψ can subtly modulate the fidelity of amino acid incorporation in a codon-position and tRNA dependent manner in vitro and in human cells. Our computational modeling shows that altered energetics of mRNA:tRNA interactions largely account for the context dependence of the low levels of miscoding we observe on Ψ and m 1 Ψ containing codons. The outcome of translation on modified mRNA bases is thus governed by the sequence context in which they occur., (© 2024. The Author(s).)

Published

2024

3. Conserved 5-methyluridine tRNA modification modulates ribosome translocation.

Author

Jones JD, Franco MK, Giles RN, Eyler DE, Tardu M, Smith TJ, Snyder LR, Polikanov YS, Kennedy RT, Niederer RO, and Koutmou KS

Subjects

RNA Processing, Post-Transcriptional, Protein Biosynthesis, Saccharomyces cerevisiae Proteins metabolism, Saccharomyces cerevisiae Proteins genetics, tRNA Methyltransferases metabolism, tRNA Methyltransferases genetics, RNA, Transfer metabolism, RNA, Transfer genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae genetics, Ribosomes metabolism, Uridine metabolism, Escherichia coli metabolism, Escherichia coli genetics

Abstract

While the centrality of posttranscriptional modifications to RNA biology has long been acknowledged, the function of the vast majority of modified sites remains to be discovered. Illustrative of this, there is not yet a discrete biological role assigned for one of the most highly conserved modifications, 5-methyluridine at position 54 in tRNAs (m 5 U54). Here, we uncover contributions of m 5 U54 to both tRNA maturation and protein synthesis. Our mass spectrometry analyses demonstrate that cells lacking the enzyme that installs m 5 U in the T-loop (TrmA in Escherichia coli , Trm2 in Saccharomyces cerevisiae ) exhibit altered tRNA modification patterns. Furthermore, m 5 U54-deficient tRNAs are desensitized to small molecules that prevent translocation in vitro. This finding is consistent with our observations that relative to wild-type cells, trm2Δ cell growth and transcriptome-wide gene expression are less perturbed by translocation inhibitors. Together our data suggest a model in which m 5 U54 acts as an important modulator of tRNA maturation and translocation of the ribosome during protein synthesis., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

4. Conserved 5-methyluridine tRNA modification modulates ribosome translocation.

Author

Jones JD, Franco MK, Tardu M, Smith TJ, Snyder LR, Eyler DE, Polikanov Y, Kennedy RT, Niederer RO, and Koutmou KS

Abstract

While the centrality of post-transcriptional modifications to RNA biology has long been acknowledged, the function of the vast majority of modified sites remains to be discovered. Illustrative of this, there is not yet a discrete biological role assigned for one the most highly conserved modifications, 5-methyluridine at position 54 in tRNAs (m 5 U54). Here, we uncover contributions of m 5 U54 to both tRNA maturation and protein synthesis. Our mass spectrometry analyses demonstrate that cells lacking the enzyme that installs m 5 U in the T-loop (TrmA in E. coli , Trm2 in S. cerevisiae ) exhibit altered tRNA modifications patterns. Furthermore, m 5 U54 deficient tRNAs are desensitized to small molecules that prevent translocation in vitro. This finding is consistent with our observations that, relative to wild-type cells, trm2 Δ cell growth and transcriptome-wide gene expression are less perturbed by translocation inhibitors. Together our data suggest a model in which m 5 U54 acts as an important modulator of tRNA maturation and translocation of the ribosome during protein synthesis.

Published

2023

5. Mapping mRNA modifications for functional studies.

Author

Jones JD, Eyler DE, and Koutmou KS

Subjects

RNA, Messenger genetics, RNA, Messenger metabolism, RNA Processing, Post-Transcriptional

Published

2023

6. Pseudouridine synthase 7 is an opportunistic enzyme that binds and modifies substrates with diverse sequences and structures.

Author

Purchal MK, Eyler DE, Tardu M, Franco MK, Korn MM, Khan T, McNassor R, Giles R, Lev K, Sharma H, Monroe J, Mallik L, Koutmos M, and Koutmou KS

Subjects

Catalytic Domain, Protein Binding, Protein Interaction Domains and Motifs, RNA, Fungal chemistry, RNA, Fungal genetics, RNA, Messenger chemistry, RNA, Messenger genetics, Stress, Physiological, Structure-Activity Relationship, Substrate Specificity, Temperature, Thermodynamics, Amino Acid Sequence, Binding Sites, Models, Molecular, Protein Conformation, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism

Abstract

Pseudouridine (Ψ) is a ubiquitous RNA modification incorporated by pseudouridine synthase (Pus) enzymes into hundreds of noncoding and protein-coding RNA substrates. Here, we determined the contributions of substrate structure and protein sequence to binding and catalysis by pseudouridine synthase 7 (Pus7), one of the principal messenger RNA (mRNA) modifying enzymes. Pus7 is distinct among the eukaryotic Pus proteins because it modifies a wider variety of substrates and shares limited homology with other Pus family members. We solved the crystal structure of Saccharomyces cerevisiae Pus7, detailing the architecture of the eukaryotic-specific insertions thought to be responsible for the expanded substrate scope of Pus7. Additionally, we identified an insertion domain in the protein that fine-tunes Pus7 activity both in vitro and in cells. These data demonstrate that Pus7 preferentially binds substrates possessing the previously identified UG U AR (R = purine) consensus sequence and that RNA secondary structure is not a strong requirement for Pus7-binding. In contrast, the rate constants and extent of Ψ incorporation are more influenced by RNA structure, with Pus7 modifying UG U AR sequences in less-structured contexts more efficiently both in vitro and in cells. Although less-structured substrates were preferred, Pus7 fully modified every transfer RNA, mRNA, and nonnatural RNA containing the consensus recognition sequence that we tested. Our findings suggest that Pus7 is a promiscuous enzyme and lead us to propose that factors beyond inherent enzyme properties (e.g., enzyme localization, RNA structure, and competition with other RNA-binding proteins) largely dictate Pus7 substrate selection., Competing Interests: The authors declare no competing interest., (Copyright © 2022 the Author(s). Published by PNAS.)

Published

2022

7. Pseudouridinylation of mRNA coding sequences alters translation.

Author

Eyler DE, Franco MK, Batool Z, Wu MZ, Dubuke ML, Dobosz-Bartoszek M, Jones JD, Polikanov YS, Roy B, and Koutmou KS

Subjects

Codon genetics, Codon metabolism, Open Reading Frames, Peptide Chain Elongation, Translational, Pseudouridine genetics, RNA Processing, Post-Transcriptional, RNA, Bacterial metabolism, RNA, Messenger metabolism, RNA, Transfer genetics, RNA, Transfer metabolism, Ribosomes genetics, Ribosomes metabolism, Thermus thermophilus metabolism, Uridine metabolism, Protein Biosynthesis, Pseudouridine metabolism, RNA, Bacterial genetics, RNA, Messenger genetics, Thermus thermophilus genetics

Abstract

Chemical modifications of RNAs have long been established as key modulators of nonprotein-coding RNA structure and function in cells. There is a growing appreciation that messenger RNA (mRNA) sequences responsible for directing protein synthesis can also be posttranscriptionally modified. The enzymatic incorporation of mRNA modifications has many potential outcomes, including changing mRNA stability, protein recruitment, and translation. We tested how one of the most common modifications present in mRNA coding regions, pseudouridine (Ψ), impacts protein synthesis using a fully reconstituted bacterial translation system and human cells. Our work reveals that replacing a single uridine nucleotide with Ψ in an mRNA codon impedes amino acid addition and EF-Tu GTPase activation. A crystal structure of the Thermus thermophilus 70S ribosome with a tRNA Phe bound to a ΨUU codon in the A site supports these findings. We also find that the presence of Ψ can promote the low-level synthesis of multiple peptide products from a single mRNA sequence in the reconstituted translation system as well as human cells, and increases the rate of near-cognate Val-tRNA Val reacting on a ΨUU codon. The vast majority of Ψ moieties in mRNAs are found in coding regions, and our study suggests that one consequence of the ribosome encountering Ψ can be to modestly alter both translation speed and mRNA decoding., Competing Interests: The authors declare no competing interest.

Published

2019

8. Mechanisms of glycosylase induced genomic instability.

Author

Eyler DE, Burnham KA, Wilson TE, and O'Brien PJ

Subjects

DNA Copy Number Variations genetics, DNA Repair genetics, Frameshift Mutation genetics, Humans, Microsatellite Repeats genetics, Mutagenesis genetics, Point Mutation genetics, Saccharomyces cerevisiae genetics, DNA Glycosylases metabolism, Mutation Accumulation

Abstract

Human alkyladenine DNA glycosylase (AAG) initiates base excision repair (BER) to guard against mutations by excising alkylated and deaminated purines. Counterintuitively, increased expression of AAG has been implicated in increased rates of spontaneous mutation in microsatellite repeats. This microsatellite mutator phenotype is consistent with a model in which AAG excises bulged (unpaired) bases, altering repeat length. To directly test the role of base excision in AAG-induced mutagenesis, we conducted mutation accumulation experiments in yeast overexpressing different variants of AAG and detected mutations via high-depth genome resequencing. We also developed a new software tool, hp_caller, to perform accurate genotyping at homopolymeric repeat loci. Overexpression of wild-type AAG elevated indel mutations in homopolymeric sequences distributed throughout the genome. However, catalytically inactive variants (E125Q/E125A) caused equal or greater increases in frameshift mutations. These results disprove the hypothesis that base excision is the key step in mutagenesis by overexpressed wild-type AAG. Instead, our results provide additional support for the previously published model wherein overexpressed AAG interferes with the mismatch repair (MMR) pathway. In addition to the above results, we observed a dramatic mutator phenotype for N169S AAG, which has increased rates of excision of undamaged purines. This mutant caused a 10-fold increase in point mutations at G:C base pairs and a 50-fold increase in frameshifts in A:T homopolymers. These results demonstrate that it is necessary to consider the relative activities and abundance of many DNA replication and repair proteins when considering mutator phenotypes, as they are relevant to the development of cancer and its resistance to treatment.

Published

2017

9. Cryoelectron microscopic structures of eukaryotic translation termination complexes containing eRF1-eRF3 or eRF1-ABCE1.

Author

Preis A, Heuer A, Barrio-Garcia C, Hauser A, Eyler DE, Berninghausen O, Green R, Becker T, and Beckmann R

Subjects

ATP-Binding Cassette Transporters metabolism, Amino Acid Motifs, Amino Acid Sequence, Cryoelectron Microscopy, Molecular Sequence Data, Peptide Termination Factors metabolism, Plant Proteins metabolism, Protein Binding, Protein Structure, Tertiary, Ribosomes ultrastructure, Saccharomyces cerevisiae Proteins metabolism, ATP-Binding Cassette Transporters chemistry, Peptide Termination Factors chemistry, Plant Proteins chemistry, Saccharomyces cerevisiae Proteins chemistry

Abstract

Termination and ribosome recycling are essential processes in translation. In eukaryotes, a stop codon in the ribosomal A site is decoded by a ternary complex consisting of release factors eRF1 and guanosine triphosphate (GTP)-bound eRF3. After GTP hydrolysis, eRF3 dissociates, and ABCE1 can bind to eRF1-loaded ribosomes to stimulate peptide release and ribosomal subunit dissociation. Here, we present cryoelectron microscopic (cryo-EM) structures of a pretermination complex containing eRF1-eRF3 and a termination/prerecycling complex containing eRF1-ABCE1. eRF1 undergoes drastic conformational changes: its central domain harboring the catalytically important GGQ loop is either packed against eRF3 or swung toward the peptidyl transferase center when bound to ABCE1. Additionally, in complex with eRF3, the N-terminal domain of eRF1 positions the conserved NIKS motif proximal to the stop codon, supporting its suggested role in decoding, yet it appears to be delocalized in the presence of ABCE1. These results suggest that stop codon decoding and peptide release can be uncoupled during termination., (Copyright © 2014 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2014

10. Eukaryotic release factor 3 is required for multiple turnovers of peptide release catalysis by eukaryotic release factor 1.

Author

Eyler DE, Wehner KA, and Green R

Subjects

Blotting, Western, Catalysis, Codon, Terminator genetics, Guanosine Triphosphate metabolism, Kinetics, Models, Genetic, Mutation, Peptide Chain Termination, Translational genetics, Peptide Termination Factors genetics, Peptides genetics, Polyribosomes genetics, Polyribosomes metabolism, Protein Binding, Protein Biosynthesis genetics, Ribosomes genetics, Ribosomes metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Peptide Termination Factors metabolism, Peptides metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Eukaryotic peptide release factor 3 (eRF3) is a conserved, essential gene in eukaryotes implicated in translation termination. We have systematically measured the contribution of eRF3 to the rates of peptide release with both saturating and limiting levels of eukaryotic release factor 1 (eRF1). Although eRF3 modestly stimulates the absolute rate of peptide release (∼5-fold), it strongly increases the rate of peptide release when eRF1 is limiting (>20-fold). This effect was generalizable across all stop codons and in a variety of contexts. Further investigation revealed that eRF1 remains associated with ribosomal complexes after peptide release and subunit dissociation and that eRF3 promotes the dissociation of eRF1 from these post-termination complexes. These data are consistent with models where eRF3 principally affects binding interactions between eRF1 and the ribosome, either prior to or subsequent to peptide release. A role for eRF3 as an escort for eRF1 into its fully accommodated state is easily reconciled with its close sequence similarity to the translational GTPase EFTu.

Published

2013

11. Inhibition of eukaryotic translation elongation by the antitumor natural product Mycalamide B.

Author

Dang Y, Schneider-Poetsch T, Eyler DE, Jewett JC, Bhat S, Rawal VH, Green R, and Liu JO

Subjects

Antineoplastic Agents chemistry, Biological Products chemistry, Cell Line, Cell Proliferation drug effects, Humans, Pyrans chemistry, Antineoplastic Agents pharmacology, Biological Products pharmacology, Peptide Chain Elongation, Translational drug effects, Pyrans pharmacology

Abstract

Mycalamide B (MycB) is a marine sponge-derived natural product with potent antitumor activity. Although it has been shown to inhibit protein synthesis, the molecular mechanism of action by MycB remains incompletely understood. We verified the inhibition of translation elongation by in vitro HCV IRES dual luciferase assays, ribosome assembly, and in vivo [(35)S]methinione labeling experiments. Similar to cycloheximide (CHX), MycB inhibits translation elongation through blockade of eEF2-mediated translocation without affecting the eEF1A-mediated loading of tRNA onto the ribosome, AUG recognition, or dipeptide synthesis. Using chemical footprinting, we identified the MycB binding site proximal to the C3993 28S rRNA residue on the large ribosomal subunit. However, there are also subtle, but significant differences in the detailed mechanisms of action of MycB and CHX. First, MycB arrests the ribosome on the mRNA one codon ahead of CHX. Second, MycB specifically blocked tRNA binding to the E-site of the large ribosomal subunit. Moreover, they display different polysome profiles in vivo. Together, these observations shed new light on the mechanism of inhibition of translation elongation by MycB.

Published

2011

12. Distinct response of yeast ribosomes to a miscoding event during translation.

Author

Eyler DE and Green R

Subjects

Paromomycin pharmacology, RNA, Transfer genetics, Ribosomes metabolism, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae metabolism, Thermodynamics, Mutation, Protein Biosynthesis, Ribosomes genetics, Saccharomyces cerevisiae genetics

Abstract

Numerous mechanisms have evolved to control the accuracy of translation, including a recently discovered retrospective quality control mechanism in bacteria. This quality control mechanism is sensitive to perturbations in the codon:anticodon interaction in the P site of the ribosome that trigger a dramatic loss of fidelity in subsequent tRNA and release factor selection events in the A site. These events ultimately lead to premature termination of translation in response to an initial miscoding error. In this work, we extend our investigations of this mechanism to an in vitro reconstituted Saccharomyces cerevisiae translation system. We report that yeast ribosomes do not respond to mismatches in the P site by loss of fidelity in subsequent substrate recognition events. We conclude that retrospective editing, as initially characterized in Escherichia coli, does not occur in S. cerevisiae. These results highlight potential mechanistic differences in the functional core of highly conserved ribosomes.

Published

2011

13. Dom34:Hbs1 promotes subunit dissociation and peptidyl-tRNA drop-off to initiate no-go decay.

Author

Shoemaker CJ, Eyler DE, and Green R

Subjects

Cell Cycle Proteins genetics, Codon, Codon, Terminator, Endoribonucleases genetics, GTP-Binding Proteins genetics, Guanosine Triphosphate metabolism, HSP70 Heat-Shock Proteins genetics, Kinetics, Peptide Chain Termination, Translational, Peptide Elongation Factors genetics, Peptide Termination Factors metabolism, Protein Biosynthesis, RNA, Fungal genetics, RNA, Messenger genetics, RNA, Transfer, Amino Acyl genetics, Recombinant Proteins metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Cell Cycle Proteins metabolism, Endoribonucleases metabolism, GTP-Binding Proteins metabolism, HSP70 Heat-Shock Proteins metabolism, Peptide Elongation Factors metabolism, RNA Stability, RNA, Fungal metabolism, RNA, Messenger metabolism, RNA, Transfer, Amino Acyl metabolism, Ribosome Subunits metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism

Abstract

No-go decay (NGD) is one of several messenger RNA (mRNA) surveillance systems dedicated to the removal of defective mRNAs from the available pool. Two interacting factors, Dom34 and Hbs1, are genetically implicated in NGD in yeast. Using a reconstituted yeast translation system, we show that Dom34:Hbs1 interacts with the ribosome to promote subunit dissociation and peptidyl-tRNA drop-off. Our data further indicate that these recycling activities are shared by the homologous translation termination factor complex eRF1:eRF3, suggesting a common ancestral function. Because Dom34:Hbs1 activity exhibits no dependence on either peptide length or A-site codon identity, we propose that this quality-control system functions broadly to recycle ribosomes throughout the translation cycle whenever stalls occur.

Published

2010

14. Inhibition of eukaryotic translation elongation by cycloheximide and lactimidomycin.

Author

Schneider-Poetsch T, Ju J, Eyler DE, Dang Y, Bhat S, Merrick WC, Green R, Shen B, and Liu JO

Abstract

Although the protein synthesis inhibitor cycloheximide (CHX) has been known for decades, its precise mechanism of action remains incompletely understood. The glutarimide portion of CHX is seen in a family of structurally related natural products including migrastatin, isomigrastatin and lactimidomycin (LTM). We found that LTM, isomigrastatin and analogs have a potent antiproliferative effect on tumor cell lines and selectively inhibit translation. A systematic comparative study of the effects of CHX and LTM on protein synthesis revealed both similarities and differences between the two inhibitors. Both LTM and CHX were found to block the translocation step in elongation. Footprinting experiments revealed protection of a single cytidine nucleotide (C3993) in the E-site of the 60S ribosomal subunit, thus defining a common binding pocket for the two inhibitors in the ribosome. These results shed new light on the molecular mechanism of inhibition of translation elongation by both CHX and LTM.

Published

2010

15. Hypusine-containing protein eIF5A promotes translation elongation.

Author

Saini P, Eyler DE, Green R, and Dever TE

Subjects

Indenes pharmacology, Mutation, Peptide Initiation Factors chemistry, Polyribosomes metabolism, Protein Synthesis Inhibitors pharmacology, RNA-Binding Proteins chemistry, Recombinant Proteins metabolism, Saccharomyces cerevisiae growth & development, Eukaryotic Translation Initiation Factor 5A, Lysine analogs & derivatives, Peptide Chain Elongation, Translational physiology, Peptide Elongation Factors metabolism, Peptide Initiation Factors metabolism, RNA-Binding Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism

Abstract

Translation elongation factors facilitate protein synthesis by the ribosome. Previous studies identified two universally conserved translation elongation factors, EF-Tu in bacteria (known as eEF1A in eukaryotes) and EF-G (eEF2), which deliver aminoacyl-tRNAs to the ribosome and promote ribosomal translocation, respectively. The factor eIF5A (encoded by HYP2 and ANB1 in Saccharomyces cerevisiae), the sole protein in eukaryotes and archaea to contain the unusual amino acid hypusine (N(epsilon)-(4-amino-2-hydroxybutyl)lysine), was originally identified based on its ability to stimulate the yield (endpoint) of methionyl-puromycin synthesis-a model assay for first peptide bond synthesis thought to report on certain aspects of translation initiation. Hypusine is required for eIF5A to associate with ribosomes and to stimulate methionyl-puromycin synthesis. Because eIF5A did not stimulate earlier steps of translation initiation, and depletion of eIF5A in yeast only modestly impaired protein synthesis, it was proposed that eIF5A function was limited to stimulating synthesis of the first peptide bond or that eIF5A functioned on only a subset of cellular messenger RNAs. However, the precise cellular role of eIF5A is unknown, and the protein has also been linked to mRNA decay, including the nonsense-mediated mRNA decay pathway, and to nucleocytoplasmic transport. Here we use molecular genetic and biochemical studies to show that eIF5A promotes translation elongation. Depletion or inactivation of eIF5A in the yeast S. cerevisiae resulted in the accumulation of polysomes and an increase in ribosomal transit times. Addition of recombinant eIF5A from yeast, but not a derivative lacking hypusine, enhanced the rate of tripeptide synthesis in vitro. Moreover, inactivation of eIF5A mimicked the effects of the eEF2 inhibitor sordarin, indicating that eIF5A might function together with eEF2 to promote ribosomal translocation. Because eIF5A is a structural homologue of the bacterial protein EF-P, we propose that eIF5A/EF-P is a universally conserved translation elongation factor.

Published

2009

16. Termination of cryptic unstable transcripts is directed by yeast RNA-binding proteins Nrd1 and Nab3.

Author

Arigo JT, Eyler DE, Carroll KL, and Corden JL

Subjects

Exonucleases metabolism, Exonucleases physiology, Mutation, Nuclear Proteins analysis, Nuclear Proteins genetics, Polyadenylation, RNA Stability, RNA, Antisense metabolism, RNA-Binding Proteins analysis, RNA-Binding Proteins genetics, Ribonucleoproteins analysis, Ribonucleoproteins genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins analysis, Saccharomyces cerevisiae Proteins genetics, Gene Expression Regulation, Fungal, Nuclear Proteins physiology, RNA, Fungal metabolism, RNA-Binding Proteins physiology, Ribonucleoproteins physiology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins physiology, Transcription, Genetic physiology

Abstract

Studies of yeast transcription have revealed the widespread distribution of intergenic RNA polymerase II transcripts. These cryptic unstable transcripts (CUTs) are rapidly degraded by the nuclear exosome. Yeast RNA binding proteins Nrd1 and Nab3 direct termination of sn/snoRNAs and recently have also been implicated in premature transcription termination of the NRD1 gene. In this paper, we show that Nrd1 and Nab3 are required for transcription termination of CUTs. In nrd1 and nab3 mutants, we observe 3'-extended transcripts originating from CUT promoters but failing to terminate through the Nrd1- and Nab3-directed pathway. Nrd1 and Nab3 colocalize to regions of the genome expressing antisense CUTs, and these transcripts require yeast nuclear exosome and TRAMP components for degradation. Dissection of a CUT terminator reveals a minimal element sufficient for Nrd1- and Nab3-directed termination. These results suggest that transcription termination of CUTs directed by Nrd1 and Nab3 is a prerequisite for rapid degradation by the nuclear exosome.

Published

2006