Diverse cell stresses induce unique patterns of tRNA up- and down-regulation: tRNA-seq for quantifying changes in tRNA copy number

Emerging evidence points to roles for tRNA modifications and tRNA abundance in cellular stress responses. While isolated instances of stress-induced tRNA degradation have been reported, we sought to assess the effects of stress on tRNA levels at a systems level. To this end, we developed a next-generation sequencing method that exploits the paucity of ribonucleoside modifications at the 3′-end of tRNAs to quantify changes in all cellular tRNA molecules. Application of this tRNA-seq method to Saccharomyces cerevisiae identified all 76 expressed unique tRNA species out of 295 coded in the yeast genome, including all isoacceptor variants, with highly precise relative (fold-change) quantification of tRNAs. In studies of stress-induced changes in tRNA levels, we found that oxidation (H₂O₂) and alkylation (methylmethane sulfonate, MMS) stresses induced nearly identical patterns of up- and down-regulation for 58 tRNAs. However, 18 tRNAs showed opposing changes for the stresses, which parallels our observation of signature reprogramming of tRNA modifications caused by H₂O₂ and MMS. Further, stress-induced degradation was limited to only a small proportion of a few tRNA species. With tRNA-seq applicable to any organism, these results suggest that translational control of stress response involves a contribution from tRNA abundance.     

Polyadenylation helps regulate functional tRNA levels in Escherichia coli

Here we demonstrate a new regulatory mechanism for tRNA processing in Escherichia coli whereby RNase T and RNase PH, the two primary 3′ → 5′ exonucleases involved in the final step of 3′-end maturation, compete with poly(A) polymerase I (PAP I) for tRNA precursors in wild-type cells. In the absence of both RNase T and RNase PH, there is a >30-fold increase of PAP I-dependent poly(A) tails that are ≤10 nt in length coupled with a 2.3- to 4.2-fold decrease in the level of aminoacylated tRNAs and a >2-fold decrease in growth rate. Only 7 out of 86 tRNAs are not regulated by this mechanism and are also not substrates for RNase T, RNase PH or PAP I. Surprisingly, neither PNPase nor RNase II has any effect on tRNA poly(A) tail length. Our data suggest that the polyadenylation of tRNAs by PAP I likely proceeds in a distributive fashion unlike what is observed with mRNAs.     

Photocross-linking analysis of the contact surface of tRNA Met in complexes with Escherichia coli methionine:tRNA ligase.

Photoinduced covalent cross-linking has been used to identify a common surface of four methionine-accepting tRNAs which interact specifically with the Escherichia coli methionine:tRNA ligase (EC 6.1.1.10). tRNA--ligase mixtures were irradiated, and the covalently linked complexes were isolated and digested with T1 RNase (Schimmel & Budzik, 1977). The fragments lost from the elution profile of the T1 RNase digest were considered to have been cross-linked to the protein and therefore in intimate contact with the enzyme. Only specific cognate tRNA--ligase pairs produce covalently linked complexes. The four substrate tRNAs used in this study have substantially different sequences, but all showed a common cross-linking pattern, supporting the view that the sites cross-linked to the enzyme reflect the functionally common contact surface rather than particularly photoreactivity regions of tRNA. The cross-linked contact surface is comprised of three regions: (1) the narrow groove of the anticodon stem and its extension into the anticodon loop; (2) the 3' terminal residues; and (3) the 3' side of the "T arm". Unlike previous studies with other tRNAs, the D arm is not involved and significant radiation damage is suffered by the tRNA which must be taken into account in the analysis. The results are consistent with and complement chemical modification studies [Schulman, L. H., & Pelka, H. (1977) Biochemistry 16, 4256].     

The nucleotide sequence of a methionine tRNA which functions in protein elongation in mouse myeloma cells.

The major form of methionine tRNA operational in the elongation of protein synthesis in mouse myeloma cells was purufied from these cells after they had been cultured in the presence of [32P]-phosphate. This [32P]tRNA4-Met species was then digested with T1 RNase or pancreatic RNase so as to obtain both complete and partial RNase digestion products. The nucleotide sequences of these fragments were analysed to enable the derivation of the complete primary structure of this tRNA. tRNA4-Met of mouse myeloma cells is 76 nucleotides in length and contains 15 modified nucleotides. It is the only tRNA yet sequenced which has been found to possess the minor nucleoside 2-methylguanosine (m2G) within the amino acid (a) stem, and also to have an anticodon (c) stem of only 4 and not 5 base-pairs. The loop IV sequence of eukaryotic initiator methionine tRNA (tRNAf-Met) species, -A-U-C-G-m1A-A-A-, IS NOT FOUND IN TRNA4-Met and is therefore absent from at least one of the methionine tRNAs functioning in polypeptide elongation in mammalian cells. This is consistent with the suggested importance of this loop structure in the initiator function of tRNAf-Met in eukaryotic organisms. Three distinct regions of the tRNA cloverleaf, the (b) stem, the anticodon loop (loop II), and loop III, are substantially conserved in structure between tRNAf-Met and tRNA4-Met of mouse myeloma cells. These regions of the structures of mammalian methionine tRNAs probably do not determine whether a certain tRNA-Met will function in the initiation or elongation of protein synthesis, although they might be important in tRNA-Met recognition if the different cytoplasmic tRNA-Met species of mammalian cells are aminoacylated by a single activating enzyme.     

The use of nuclease P1 in sequence analysis of end group labeled RNA.

A method is described for the direct sequence analysis of 20-25 nucleotides from the termini of 5'- or 3'-end-group [32P] labeled RNA. The method involves partial endonucleolytic digestion of the labeled RNA with nuclease P1 (from Penicillium citrinum) followed by separation of the partial digestion products by two-dimensional homochromatography, the nucleotide sequence being determined by mobility shift analysis. This procedure has been applied to the sequence analysis of the terminal regions of tRNAs and of high molecular weight RNA, such as messenger RNA or viral RNA. A further application involves its use in conjunction with snake venom phosphodiesterase to determine the sequence of 5'-end group labeled oligonucleotides, containing modified bases, derived from T1 or pancreatic RNase digestion of tRNA.     

tRNA accumulation and suppression of the bldA phenotype during development in Streptomyces coelicolor

Streptomyces coelicolor undergoes distinct morphological changes as it grows on solid media where spores differentiate into vegetative and aerial mycelium that is followed by the production of spores. Deletion of bldA, encoding the rare tRNA(Leu) UAA, blocks development at the stage of vegetative mycelium formation. From previous data it appears that tRNA(Leu) UAA accumulates relatively late during growth while two other tRNAs do not. Here, we studied the expression of 17 different tRNAs including bldA tRNA, and the RNA subunit of the tRNA processing endoribonuclease RNase P. Our results showed that all selected tRNAs and RNase P RNA increased with time during development. However, accumulation of bldA tRNA and another rare tRNA(Leu) isoacceptor started at an earlier stage compared with the other tRNAs. We also introduced the bldA tRNA anticodon (UAA) into other tRNAs and introduced these into a bldA deletion strain. In particular, one such mutant tRNA derived from the tRNA(Leu) CAA isoacceptor suppressed the bldA phenotype. Thus, the bldA tRNA scaffold is not critical for function as a regulator of S. coelicolor cell differentiation. Further substitution experiments, in which the 5'- and 3'-flanking regions of the suppressor tRNA were changed, indicated that these regions were important for the suppression.     

Identification of nuclear encoded precursor tRNAs within the mitochondrion of Trypanosoma brucei.

RNAs that function in mitochondria are typically encoded by the mitochondrial DNA. However, the mitochondrial tRNAs of Trypanosoma brucei are encoded by the nuclear DNA and therefore must be imported into the mitochondrion. It is becoming evident that RNA import into mitochondria is phylogenetically widespread and is essential for cellular processes, but virtually nothing is known about the mechanism of RNA import. We have identified and characterized mitochondrial precursor tRNAs in T. brucei. The identification of mitochondrially located precursor tRNAs clearly indicates that mitochondrial tRNAs are imported as precursors. The mitochondrial precursor tRNAs hybridize to cloned nuclear tRNA genes, label with [alpha-32P]CTP using yeast tRNA nucleotidyltransferase and in isolated mitochondria via an endogenous nucleotidyltransferase-like activity, and are processed to mature tRNAs by Escherichia coli and yeast mitochondrial RNase P. We show that T. brucei mitochondrial extract contains an RNase P activity capable of processing a prokaryotic tRNA precursor as well as the T. brucei tRNA precursors. Precursors for tRNA(Asn) and tRNA(Leu) were detected on Northern blots of mitochondrial RNA, and the 5' ends of these RNAs were characterized by primer extension analysis. The structure of the precursor tRNAs and the significance of nuclear encoded precursor tRNAs within the mitochondrion are discussed.     

Different conformations of tRNA in the ribosomal P-site and A-site

Footprinting studies involving radioactively end-labelled tRNA species bound at either the ribosomal P- or A-site have yielded information that the tRNA's conformation is different in the two sites. Appropriate controls showed the relevance of using poly(U)-directed tRNAPhe binding in the P-site and Phe-tRNAPhe in the A-site. Digestion of the tRNA species was effected by RNases T1, T2 and cobra venom RNase. Experiments were performed with tRNAs 32P-labelled at either end to establish positions of primary cuts more confidently. In addition to the common protection of the aminoacyl-stem and anticodon-arm, footprinting experiments revealed striking differences in the accessibility of the T- and D-loops of tRNAs bound in the P- and A-sites. We observed a more open structure for the tRNA in the A-site. These results are consistent with a dynamic structure of tRNA during the translocation step of protein biosynthesis.     

S1 nuclease as a probe for the conformation of a dimeric tRNA precursor.

We have employed S1 nuclease to probe the structure of an intermediate in tRNA biosynthesis available only in radiochemical purity. The dimeric precursor to tRNAGln and tRNALeu from bacteriophage T4 was digested with the single-strand specific nuclease, and the products of the reaction were compared with the S1 digestion products of the mature cognate tRNA'S. Quantitation and sequence analysis of the products revealed that the location and accessibility of S1 cleavage sites in the precursor were substantially identical with those in the mature forms. Based on these conclusions, it is argued that the dimer is comprised of two domains in which the specific features of both secondary and tertiary conformation closely resemble those found in the mature molecules; at the same time we noted small but apparently significant differences in certain regions of the molecule which may reflect signals for various maturation events. Finally, we have determined that the sites of precursor cleavage by RNase P, the endonuclease which generates the mature 5' termini of these tRNAs, were completely inaccessible to S1 digestion.     

The nucleotide sequences of the two glutamine transfer ribonucleic acids from Escherichia coli.

The nucleotide sequences of the two glutamine tRNA species in Escherichia coli K12 have been determined. Sufficient data was obtained to order unambiguously the products of complete RNase digestion of tRNA2Gln, and all but one oligonucleotide from tRNA1Gln. The sequence of tRNA1Gln was established by analogy with tRNA1Gln, as the two tRNAs are very similar, differing by only 7 residues out of 75. tRNA1Gln has the anticodon NUG, where N is a modified nucleotide which is likely to be a derivative of 2-thiouridine, and is specific for the codon CAA. tRNA1Gln has the anticodon CUG, and is specific for the codon CAG (Folk, W. R., and Yaniv, M. (1972) Nature 237, 165). The complete sequences of the tRNAGln species are: See journal for formula (Unique residues are enclosed in parentheses, with the residue in tRNA1Gln above that in tRNA2Gln.).     

Deregulation of poly(A) polymerase I in Escherichia coli inhibits protein synthesis and leads to cell death

Polyadenylation plays important roles in RNA metabolism in both prokaryotes and eukaryotes. Surprisingly, deregulation of polyadenylation by poly(A) polymerase I (PAP I) in Escherichia coli leads to toxicity and cell death. We show here that mature tRNAs, which are normally not substrates for PAP I in wild-type cells, are rapidly polyadenylated as PAP I levels increase, leading to dramatic reductions in the fraction of aminoacylated tRNAs, cessation of protein synthesis and cell death. The toxicity associated with PAP I is exacerbated by the absence of either RNase T and/or RNase PH, the two major 3′ → 5′ exonucleases involved in the final step of tRNA 3′-end maturation, confirming their role in the regulation of tRNA polyadenylation. Furthermore, our data demonstrate that regulation of PAP I is critical not for preventing the decay of mRNAs, but rather for maintaining normal levels of functional tRNAs and protein synthesis in E. coli, a function for polyadenylation that has not been observed previously in any organism.     

The C nucleotide at the mature 5′ end of the Escherichia coli proline tRNAs is required for the RNase E cleavage specificity at the 3′ terminus as well as functionality

Proline tRNA 3′-maturation in Escherichia coli occurs through a one-step RNase E endonucleolytic cleavage immediately after the CCA determinant. This processing pathway is distinct from the 3′-end maturation of the other tRNAs by avoiding the widespread use of 3′ → 5′ exonucleolytic processing, 3′-polyadenylation and subsequent degradation. Here, we show that the cytosine (C) at the mature 5′-terminus of the proK and proL tRNAs is required for both the RNase E cleavage immediately after the CCA determinant and their functionality. Thus, changing the C nucleotide at the mature 5′-terminus of the proL and proK tRNAs to the more common G nucleotide led to RNase E cleavages 1–4 nucleotides downstream of the CCA determinant. Furthermore, the 5′-modified mutant tRNAs required RNase T and RNase PH for their 3′-maturation and became substrates for polyadenylation and degradation. Strikingly, the aminoacylation of the 5′-modified proline tRNAs was blocked due to the change in the recognition element for prolyl-tRNA-synthetase. An analogous modification of the pheV 5′-mature terminus from G to C nucleotide did not support cell viability. This result provides additional support for the importance of first nucleotide of the mature tRNAs in their processing and functionality.     

tRNAs in Trypanosoma brucei: genomic organization, expression, and mitochondrial import

The mitochondrial genome of Trypanosoma brucei does not encode tRNAs. Consequently, all mitochondrial tRNAs are imported from the cytosol and originate from nucleus-encoded genes. Analysis of all currently available T. brucei sequences revealed that its genome carries 50 tRNA genes representing 40 different isoacceptors. The identified set is expected to be nearly complete since all but four codons are accounted for. The number of tRNA genes in T. brucei is very low for a eukaryote and lower than those of many prokaryotes. Using quantitative Northern analysis we have determined the absolute abundance in the cell and the mitochondrion of a group of 15 tRNAs specific for 12 amino acids. Except for the initiator type tRNA(Met), which is cytosol specific, the cytosolic and the mitochondrial sets of tRNAs were qualitatively identical. However, the extent of mitochondrial localization was variable for the different tRNAs, ranging from 1 to 7.5% per cell. Finally, by using transgenic cell lines in combination with quantitative Northern analysis it was shown that import of tRNA(Leu)(CAA) is independent of its 5'-genomic context, suggesting that the in vivo import substrate corresponds to the mature, fully processed tRNA.