Loss of Anticodon Wobble Uridine Modifications Affects tRNALys Function and Protein Levels in Saccharomyces cerevisiae

In eukaryotes, wobble uridines in the anticodons of tRNA^Lys _UUU, tRNA^Glu _UUC and tRNA^Gln _UUG are modified to 5-methoxy-carbonyl-methyl-2-thio-uridine (mcm⁵s²U). While mutations in subunits of the Elongator complex (Elp1-Elp6), which disable mcm⁵ side chain formation, or removal of components of the thiolation pathway (Ncs2/Ncs6, Urm1, Uba4) are individually tolerated, the combination of both modification defects has been reported to have lethal effects on Saccharomyces cerevisiae. Contrary to such absolute requirement of mcm⁵s²U for viability, we demonstrate here that in the S. cerevisiae S288C-derived background, both pathways can be simultaneously inactivated, resulting in combined loss of tRNA anticodon modifications (mcm⁵U and s²U) without a lethal effect. However, an elp3 disruption strain displays synthetic sick interaction and synergistic temperature sensitivity when combined with either uba4 or urm1 mutations, suggesting major translational defects in the absence of mcm⁵s²U modifications. Consistent with this notion, we find cellular protein levels drastically decreased in an elp3uba4 double mutant and show that this effect as well as growth phenotypes can be partially rescued by excess of tRNA^Lys _UUU. These results may indicate a global translational or protein homeostasis defect in cells simultaneously lacking mcm⁵ and s² wobble uridine modification that could account for growth impairment and mainly originates from tRNA^Lys _UUU hypomodification and malfunction.     

Trm112p Is a 15-kDa Zinc Finger Protein Essential for the Activity of Two tRNA and One Protein Methyltransferases in Yeast

The degenerate base at position 34 of the tRNA anticodon is the target of numerous modification enzymes. In Saccharomyces cerevisiae, five tRNAs exhibit a complex modification of uridine 34 (mcm⁵U₃₄ and mcm⁵s²U₃₄), the formation of which requires at least 25 different proteins. The addition of the last methyl group is catalyzed by the methyltransferase Trm9p. Trm9p interacts with Trm112p, a 15-kDa protein with a zinc finger domain. Trm112p is essential for the activity of Trm11p, another tRNA methyltransferase, and for Mtq2p, an enzyme that methylates the translation termination factor eRF1/Sup45. Here, we report that Trm112p is required in vivo for the formation of mcm⁵U₃₄ and mcm⁵s²U₃₄. When produced in Escherichia coli, Trm112p forms a complex with Trm9p, which renders the latter soluble. This recombinant complex catalyzes the formation of mcm⁵U₃₄ on tRNA in vitro but not mcm⁵s²U₃₄. An mtq2-0 trm9-0 strain exhibits a synthetic growth defect, thus revealing the existence of an unexpected link between tRNA anticodon modification and termination of translation. Trm112p is associated with other partners involved in ribosome biogenesis and chromatin remodeling, suggesting that it has additional roles in the cell.     

Functional importance of Ψ38 and Ψ39 in distinct tRNAs,amplified for tRNAGln(UUG) by unexpected temperature sensitivity of the s2U modification in yeast

The numerous modifications of tRNA play central roles in controlling tRNA structure and translation. Modifications in and around the anticodon loop often have critical roles in decoding mRNA and in maintaining its reading frame. Residues U₃₈ and U₃₉ in the anticodon stem–loop are frequently modified to pseudouridine (Ψ) by members of the widely conserved TruA/Pus3 family of pseudouridylases. We investigate here the cause of the temperature sensitivity of pus3Δ mutants of the yeast Saccharomyces cerevisiae and find that, although Ψ₃₈ or Ψ₃₉ is found on at least 19 characterized cytoplasmic tRNA species, the temperature sensitivity is primarily due to poor function of tRNA^Gln(UUG), which normally has Ψ₃₈. Further investigation reveals that at elevated temperatures there are substantially reduced levels of the s²U moiety of mcm⁵s²U₃₄ of tRNA^Gln(UUG) and the other two cytoplasmic species with mcm⁵s²U₃₄, that the reduced s²U levels occur in the parent strain BY4741 and in the widely used strain W303, and that reduced levels of the s²U moiety are detectable in BY4741 at temperatures as low as 33°C. Additional examination of the role of Ψ_38,39 provides evidence that Ψ₃₈ is important for function of tRNA^Gln(UUG) at permissive temperature, and indicates that Ψ₃₉ is important for the function of tRNA^Trp(CCA) in trm10Δ pus3Δ mutants and of tRNA^Leu(CAA) as a UAG nonsense suppressor. These results provide evidence for important roles of both Ψ₃₈ and Ψ₃₉ in specific tRNAs, and establish that modification of the wobble position is subject to change under relatively mild growth conditions.     

The role of wobble uridine modifications in +1 translational frameshifting in eukaryotes

In Saccharomyces cerevisiae, 11 out of 42 tRNA species contain 5-methoxycarbonylmethyl-2-thiouridine (mcm⁵s²U), 5-methoxycarbonylmethyluridine (mcm⁵U), 5-carbamoylmethyluridine (ncm⁵U) or 5-carbamoylmethyl-2′-O-methyluridine (ncm⁵Um) nucleosides in the anticodon at the wobble position (U₃₄). Earlier we showed that mutants unable to form the side chain at position 5 (ncm⁵ or mcm⁵) or lacking sulphur at position 2 (s²) of U₃₄ result in pleiotropic phenotypes, which are all suppressed by overexpression of hypomodified tRNAs. This observation suggests that the observed phenotypes are due to inefficient reading of cognate codons or an increased frameshifting. The latter may be caused by a ternary complex (aminoacyl-tRNA*eEF1A*GTP) with a modification deficient tRNA inefficiently being accepted to the ribosomal A-site and thereby allowing an increased peptidyl-tRNA slippage and thus a frameshift error. In this study, we have investigated the role of wobble uridine modifications in reading frame maintenance, using either the Renilla/Firefly luciferase bicistronic reporter system or a modified Ty1 frameshifting site in a HIS4A::lacZ reporter system. We here show that the presence of mcm⁵ and s² side groups at wobble uridines are important for reading frame maintenance and thus the aforementioned mutant phenotypes might partly be due to frameshift errors.     

Combination of the Loss of cmnmU34 with the Lack of sU34 Modifications of tRNA, tRNA, and tRNA Altered Mitochondrial Biogenesis and Respiration

Yeast Saccharomyces cerevisiae MTO2, MTO1, and MSS1 genes encoded highly conserved tRNA modifying enzymes for the biosynthesis of carboxymethylaminomethyl (cmnm)⁵s²U₃₄ in mitochondrial tRNA^Lys, tRNA^Glu, and tRNA^Gln. In fact, Mto1p and Mss1p are involved in the biosynthesis of the cmnm⁵ group (cmnm⁵U₃₄), while Mto2p is responsible for the 2-thiouridylation (s²U₃₄) of these tRNAs. Previous studies showed that partial modifications at U₃₄ in mitochondrial tRNA enabled mto1, mto2, and mss1 strains to respire. In this report, we investigated the functional interaction between MTO2, MTO1, and MSS1 genes by using the mto2, mto1, and mss1 single, double, and triple mutants. Strikingly, the deletion of MTO2 was synthetically lethal with a mutation of MSS1 or deletion of MTO1 on medium containing glycerol but not on medium containing glucose. Interestingly, there were no detectable levels of nine tRNAs including tRNA^Lys, tRNA^Glu, and tRNA^Gln in mto2/mss1, mto2/mto1, and mto2/mto1/mss1 strains. Furthermore, mto2/mss1, mto2/mto1, and mto2/mto1/mss1 mutants exhibited extremely low levels of COX1 and CYTB mRNA and 15S and 21S rRNA as well as the complete loss of mitochondrial protein synthesis. The synthetic enhancement combinations likely resulted from the completely abolished modification at U₃₄ of tRNA^Lys, tRNA^Glu, and tRNA^Gln, caused by the combination of eliminating the 2-thiouridylation by the mto2 mutation with the absence of the cmnm⁵U₃₄ by the mto1 or mss1 mutation. The complete loss of modifications at U₃₄ of tRNAs altered mitochondrial RNA metabolisms, causing a degradation of mitochondrial tRNA, mRNA, and rRNAs. As a result, failures in mitochondrial RNA metabolisms were responsible for the complete loss of mitochondrial translation. Consequently, defects in mitochondrial protein synthesis caused the instability of their mitochondrial genomes, thus producing the respiratory-deficient phenotypes. Therefore, our findings demonstrated a critical role of modifications at U₃₄ of tRNA^Lys, tRNA^Glu, and tRNA^Gln in maintenance of mitochondrial genome, mitochondrial RNA stability, translation, and respiratory function.     

Familial dysautonomia (FD) patients have reduced levels of the modified wobble nucleoside mcmsU in tRNA

Familial dysautonomia (FD) is a recessive neurodegenerative genetic disease. FD is caused by a mutation in the IKBKAP gene resulting in a splicing defect and reduced levels of full length IKAP protein. IKAP homologues can be found in all eukaryotes and are part of a conserved six subunit protein complex, Elongator complex. Inactivation of any Elongator subunit gene in multicellular organisms cause a wide range of phenotypes, suggesting that Elongator has a pivotal role in several cellular processes. In yeast, there is convincing evidence that the main role of Elongator complex is in formation of modified wobble uridine nucleosides in tRNA and that their absence will influence translational efficiency. To date, no study has explored the possibility that FD patients display defects in formation of modified wobble uridine nucleosides as a consequence of reduced IKAP levels. In this study, we show that brain tissue and fibroblast cell lines from FD patients have reduced levels of the wobble uridine nucleoside 5-methoxycarbonylmethyl-2-thiouridine (mcm⁵s²U). Our findings indicate that FD could be caused by inefficient translation due to lower levels of wobble uridine nucleosides.     

A yeast tRNA mutant that causes pseudohyphal growth exhibits reduced rates of CAG codon translation

In Saccharomyces cerevisiae, the SUP70 gene encodes the CAG‐decoding tRNA^Gln_CUG. A mutant allele, sup70‐65, induces pseudohyphal growth on rich medium, an inappropriate nitrogen starvation response. This mutant tRNA is also a UAG nonsense suppressor via first base wobble. To investigate the basis of the pseudohyphal phenotype, 10 novel sup70 UAG suppressor alleles were identified, defining positions in the tRNA^Gln_CUG anticodon stem that restrict first base wobble. However, none conferred pseudohyphal growth, showing altered CUG anticodon presentation cannot itself induce pseudohyphal growth. Northern blot analysis revealed the sup70‐65 tRNA^Gln_CUG is unstable, inefficiently charged, and 80% reduced in its effective concentration. A stochastic model simulation of translation predicted compromised expression of CAG‐rich ORFs in the tRNA^Gln_CUG‐depleted sup70‐65 mutant. This prediction was validated by demonstrating that luciferase expression in the mutant was 60% reduced by introducing multiple tandem CAG (but not CAA) codons into this ORF. In addition, the sup70‐65 pseudohyphal phenotype was partly complemented by overexpressing CAA‐decoding tRNA^Gln_UUG, an inefficient wobble‐decoder of CAG. We thus show that introducing codons decoded by a rare tRNA near the 5′ end of an ORF can reduce eukaryote translational expression, and that the mutant tRNA_CUG^Gln constitutive pseudohyphal differentiation phenotype correlates strongly with reduced CAG decoding efficiency.     

Archaeal Tuc1/Ncs6 Homolog Required for Wobble Uridine tRNA Thiolation Is Associated with Ubiquitin-Proteasome,Translation, and RNA Processing System Homologs

While cytoplasmic tRNA 2-thiolation protein 1 (Tuc1/Ncs6) and ubiquitin-related modifier-1 (Urm1) are important in the 2-thiolation of 5-methoxycarbonylmethyl-2-thiouridine (mcm⁵s²U) at wobble uridines of tRNAs in eukaryotes, the biocatalytic roles and properties of Ncs6/Tuc1 and its homologs are poorly understood. Here we present the first report of an Ncs6 homolog of archaea (NcsA of Haloferax volcanii) that is essential for maintaining cellular pools of thiolated tRNA^Lys_UUU and for growth at high temperature. When purified from Hfx. volcanii, NcsA was found to be modified at Lys204 by isopeptide linkage to polymeric chains of the ubiquitin-fold protein SAMP2. The ubiquitin-activating E1 enzyme homolog of archaea (UbaA) was required for this covalent modification. Non-covalent protein partners that specifically associated with NcsA were also identified including UbaA, SAMP2, proteasome activating nucleotidase (PAN)-A/1, translation elongation factor aEF-1α and a β-CASP ribonuclease homolog of the archaeal cleavage and polyadenylation specificity factor 1 family (aCPSF1). Together, our study reveals that NcsA is essential for growth at high temperature, required for formation of thiolated tRNA^Lys_UUU and intimately linked to homologs of ubiquitin-proteasome, translation and RNA processing systems.     

Chromosomal assignment of a large tRNA gene cluster (tRNALeu,tRNAGln, tRNALys,tRNAArg, tRNAGly) to 17p13.1

Summary A cluster of tRNA genes (tRNA _UAG ^Leu , tRNA _CUG ^Gln , tRNA _UUU ^Lys , tRNA _UCU ^Arg ) and an adjacent tRNA _GCC ^Gly have been assigned to human chromosome 17p12–p13.1 by in situ hybridization using a 4.2 kb human DNA fragment for tRNA^Leu, tRNA^Gln, tRNA^Lys, tRNA^Arg, and, for tRNA^Gly, 1.3 kb and 0.58 kb human DNA fragments containing these genes as probes. This localization was confirmed and refined to 17p13.100–p13.105 using a somatic cell hybrid mapping panel. Preliminary experiments with the biotiny lated tRNA Leu, Gln, Lys, Arg probe and metaphase spreads from other great apes suggest the presence of a hybridization site on the long arm of gorilla (Gorilla gorilla) chromosome 19 and the short arm of orangutan (Pongo pygmaeus) chromosome 19 providing further support for homology between HSA17, GGO19 and PPY19.     

Combined tRNA modification defects impair protein homeostasis and synthesis of the yeast prion protein Rnq1

Modified nucleosides in tRNA anticodon loops such as 5-methoxy-carbonyl-methyl-2-thiouridine (mcm⁵s²U) and pseuduridine (Ψ) are thought to be required for an efficient decoding process. In Saccharomyces cerevisiae, the simultaneous presence of mcm⁵s²U and Ψ38 in tRNA^Gln_UUG was shown to mediate efficient synthesis of the Q/N rich [PIN⁺] prion forming protein Rnq1.¹ Klassen R, Ciftci A, Johanna Funk J, Bruch A, Butter F, Schaffrath R. tRNA anticodon loop modifications ensure protein homeostasis and cell morphogenesis in yeast. Nucleic Acids Res 2016; 44(22):10946-959. pii: gkw705; PMID:27496282; http://dx.doi.org/10.1093/nar/gkw705[Crossref], [PubMed], [Web of Science ®] [Google Scholar] In the absence of these two tRNA modifications, higher than normal levels of hypomodified tRNA^Gln_UUG, but not its isoacceptor tRNA^Gln_CUG can restore Rnq1 synthesis. Moroever, tRNA overexpression rescues pleiotropic phenotypes that associate with loss of mcm⁵s²U and Ψ38 formation. Notably, combined absence of different tRNA modifications are shown to induce the formation of protein aggregates which likely mediate severe cytological abnormalities, including cytokinesis and nuclear segregation defects. In support of this, overexpression of the aggregating polyQ protein Htt103Q, but not its non-aggregating variant Htt25Q phenocopies these cytological abnormalities, most pronouncedly in deg1 single mutants lacking Ψ38 alone. It is concluded that slow decoding of particular codons induces defects in protein homeostasis that interfere with key steps in cytokinesis and nuclear segregation.     

Specificity of Phage Display Selected Peptides for Modified Anticodon Stem and Loop Domains of tRNA

Protein recognition of RNA has been studied using Peptide Phage Display Libraries, but in the absence of RNA modifications. Peptides from two libraries, selected for binding the modified anticodon stem and loop (ASL) of human tRNA^Lys3 having 2-thiouridine (s²U₃₄) and pseudouridine (Ψ₃₉), bound the modified human ASL^Lys3(s²U₃₄;Ψ₃₉) preferentially and had significant homology with RNA binding proteins. Selected peptides were narrowed to a manageable number using a less sensitive, but inexpensive assay before conducting intensive characterization. The affinity and specificity of the best binding peptide (with an N-terminal fluorescein) were characterized by fluorescence spectrophotometry. The peptide exhibited the highest binding affinity for ASL^Lys3(s²U₃₄;Ψ₃₉), followed by the hypermodified ASL^Lys3 (mcm⁵s²U₃₄;ms²t⁶A₃₇) and the unmodified ASL^Lys3, but bound poorly to singly modified ASL^Lys3 constructs (Ψ₃₉, ms²t⁶A_37, s²U₃₄), ASL^Lys1,2 (t⁶A₃₇) and Escherichia coli ASL^Glu (s²U₃₄). Thus, RNA modifications are potentially important recognition elements for proteins and can be targets for selective recognition by peptides.     

Mammalian ALKBH8 Possesses tRNA Methyltransferase Activity Required for the Biogenesis of Multiple Wobble Uridine Modifications Implicated in Translational Decoding

Uridines in the wobble position of tRNA are almost invariably modified. Modifications can increase the efficiency of codon reading, but they also prevent mistranslation by limiting wobbling. In mammals, several tRNAs have 5-methoxycarbonylmethyluridine (mcm⁵U) or derivatives thereof in the wobble position. Through analysis of tRNA from Alkbh8^−/− mice, we show here that ALKBH8 is a tRNA methyltransferase required for the final step in the biogenesis of mcm⁵U. We also demonstrate that the interaction of ALKBH8 with a small accessory protein, TRM112, is required to form a functional tRNA methyltransferase. Furthermore, prior ALKBH8-mediated methylation is a prerequisite for the thiolation and 2′-O-ribose methylation that form 5-methoxycarbonylmethyl-2-thiouridine (mcm⁵s²U) and 5-methoxycarbonylmethyl-2′-O-methyluridine (mcm⁵Um), respectively. Despite the complete loss of all of these uridine modifications, Alkbh8^−/− mice appear normal. However, the selenocysteine-specific tRNA (tRNA^Sec) is aberrantly modified in the Alkbh8^−/− mice, and for the selenoprotein Gpx1, we indeed observed reduced recoding of the UGA stop codon to selenocysteine.tRNAs are frequently modified at the wobble uridine, a feature that is believed to either promote or restrict wobbling depending on the type of modification. In the case of eukaryotes, the functions of wobble uridine modifications have been studied in the greatest detail in Saccharomyces cerevisiae. Here, the modifications 5-methoxycarbonylmethyluridine (mcm⁵U), 5-methoxycarbonylmethyl-2-thiouridine (mcm⁵s²U), and 5-carbamoylmethyluridine (ncm⁵U) or its 2′-O-ribose-methylated form, ncm⁵Um, are found in 11 out of 13 wobble uridine-containing tRNAs (22). mcm⁵U and mcm⁵s²U are mostly found in “split” codon boxes, where the pyrimidine- and purine-ending codons encode different amino acids, while ncm⁵U is found in “family” codon boxes, where all four codons encode a single amino acid. Early reports based on in vitro experiments suggested that wobble nucleosides, such as mcm⁵U, ncm⁵U, and their derivatives, may restrict wobbling (17, 37, 45), but the results of a recent comprehensive study performed in vivo in S. cerevisiae show that such modifications can improve the reading both of the cognate, A-ending codons and of the wobble, G-ending codons (22). This may suggest that the primary role of these modified nucleosides is to improve translational efficiency rather than to restrict wobbling.The characterization of wobble uridine modifications in higher eukaryotes is very limited, and little is known about the enzymes that introduce them. In mammals, mcm⁵s²U has been found in the wobble position of tRNA^Glu(UUC), tRNA^Lys(UUU), and tRNA^Arg(UCU) (40). Unlike yeast, mammals possess a specialized tRNA that is responsible for recoding the UGA stop codon to insert the 21st amino acid, selenocysteine (Sec). The mammalian tRNA^Sec population consists of two subpopulations containing either mcm⁵U or the ribose-methylated derivative mcm⁵Um in the wobble position. Interestingly, ribose methylation of mcm⁵U in tRNA^Sec appears to have a role in regulating selenoprotein synthesis, as the expression of some selenoproteins, such as glutathione peroxidase 1 (Gpx1), appears to be promoted by mcm⁵Um-containing tRNA^Sec (5, 7, 9, 32).Some years ago, the Escherichia coli AlkB protein was found to be a 2-oxoglutarate- and iron-dependent dioxygenase capable of demethylating the lesions 1-methyladenosine and 3-methylcytosine in DNA (13, 42). Multicellular organisms generally possess several different AlkB homologues (ALKBH), and bioinformatics analysis has identified eight different mammalian ALKBH proteins, denoted ALKBH1 to ALKBH8 in humans and Alkbh1 to Alkbh8 in mice, as well as the somewhat-less-related, obesity-associated FTO protein (2, 16, 30). Among the ALKBH proteins of unknown function, ALKBH8 is the only one containing additional annotated protein domains. Here, the AlkB domain is localized between an N-terminal RNA recognition motif (RRM) and a C-terminal methyltransferase (MT) domain. Interestingly, the MT domain has sequence homology to the S. cerevisiae tRNA methyltransferase Trm9, which has been shown to catalyze the methyl esterification of modified wobble uridine (U34) residues of tRNA^Arg and tRNA^Glu, resulting in the formation of mcm⁵U and mcm⁵s²U, respectively (23, 43). Until recently, human ALKBH8 was incorrectly annotated in the protein sequence database, and another human protein, KIAA1456, has been designated the human Trm9 homologue (3, 23).We have generated for this study Alkbh8-targeted mice that lack exons critical for both the MT and AlkB activities of Alkbh8. The mice did not display any overt phenotype, but tRNA from these mice was completely devoid of mcm⁵U, mcm⁵s²U, and mcm⁵Um, and the relevant tRNA isoacceptors instead contained the acid form 5-carboxymethyluridine (cm⁵U) and/or the amide forms ncm⁵U/ncm⁵s²U. Furthermore, we show that recombinant ALKBH8 and TRM112 form a heterodimeric complex capable of catalyzing the methyl esterification of cm⁵U and cm⁵s²U to mcm⁵U and mcm⁵s²U, respectively. In agreement with the involvement of mcm⁵Um in selenoprotein synthesis, we observed a reduced level of Gpx1 in the Alkbh8^−/− mice, and tRNA^Sec from these mice showed a reduced ability to decode the UGA stop codon to Sec.     

Loss of a Conserved tRNA Anticodon Modification Perturbs Cellular Signaling

Transfer RNA (tRNA) modifications enhance the efficiency, specificity and fidelity of translation in all organisms. The anticodon modification mcm⁵s²U³⁴ is required for normal growth and stress resistance in yeast; mutants lacking this modification have numerous phenotypes. Mutations in the homologous human genes are linked to neurological disease. The yeast phenotypes can be ameliorated by overexpression of specific tRNAs, suggesting that the modifications are necessary for efficient translation of specific codons. We determined the in vivo ribosome distributions at single codon resolution in yeast strains lacking mcm⁵s²U. We found accumulations at AAA, CAA, and GAA codons, suggesting that translation is slow when these codons are in the ribosomal A site, but these changes appeared too small to affect protein output. Instead, we observed activation of the GCN4-mediated stress response by a non-canonical pathway. Thus, loss of mcm⁵s²U causes global effects on gene expression due to perturbation of cellular signaling.     

Elongator—a tRNA modifying complex that promotes efficient translational decoding

Naturally occurring modifications of the nucleosides in the anticodon region of tRNAs influence their translational decoding properties. Uridines present at the wobble position in eukaryotic cytoplasmic tRNAs often contain a 5-carbamoylmethyl (ncm⁵) or 5-methoxycarbonylmethyl (mcm⁵) side-chain and sometimes also a 2-thio or 2′-O-methyl group. The first step in the formation of the ncm⁵ and mcm⁵ side-chains requires the conserved six-subunit Elongator complex. Although Elongator has been implicated in several different cellular processes, accumulating evidence suggests that its primary, and possibly only, cellular function is to promote modification of tRNAs. In this review, we discuss the biosynthesis and function of modified wobble uridines in eukaryotic cytoplasmic tRNAs, focusing on the in vivo role of Elongator-dependent modifications in Saccharomyces cerevisiae. This article is part of a Special Issue entitled: SI: Regulation of tRNA synthesis and modification in physiological conditions and disease edited by Dr. Boguta Magdalena.     

tRNA thiolation links translation to stress responses in Saccharomyces cerevisiae

Although tRNA modifications have been well catalogued, the precise functions of many modifications and their roles in mediating gene expression are still being elucidated. Whereas tRNA modifications were long assumed to be constitutive, it is now apparent that the modification status of tRNAs changes in response to different environmental conditions. The URM1 pathway is required for thiolation of the cytoplasmic tRNAs tGlu^UUC, tGln^UUG, and tLys^UUU in Saccharomyces cerevisiae. We demonstrate that URM1 pathway mutants have impaired translation, which results in increased basal activation of the Hsf1-mediated heat shock response; we also find that tRNA thiolation levels in wild-type cells decrease when cells are grown at elevated temperature. We show that defects in tRNA thiolation can be conditionally advantageous, conferring resistance to endoplasmic reticulum stress. URM1 pathway proteins are unstable and hence are more sensitive to changes in the translational capacity of cells, which is decreased in cells experiencing stresses. We propose a model in which a stress-induced decrease in translation results in decreased levels of URM1 pathway components, which results in decreased tRNA thiolation levels, which further serves to decrease translation. This mechanism ensures that tRNA thiolation and translation are tightly coupled and coregulated according to need.