Schizosaccharomyces pombe contains separate CC- and A-adding tRNA nucleotidyltransferases

A specific cytidine-cytidine-adenosine (CCA) sequence is required at the 3′-terminus of all functional tRNAs. This sequence is added during tRNA maturation or repair by tRNA nucleotidyltransferase enzymes. While most eukaryotes have a single enzyme responsible for CCA addition, some bacteria have separate CC- and A-adding activities. The fungus, Schizosaccharomyces pombe, has two genes (cca1 and cca2) that are thought, based on predicted amino acid sequences, to encode tRNA nucleotidyltransferases. Here, we show that both genes together are required to complement a Saccharomyces cerevisiae strain bearing a null mutation in the single gene encoding its tRNA nucleotidyltransferase. Using enzyme assays we show further that the purified S. pombe cca1 gene product specifically adds two cytidine residues to a tRNA substrate lacking this sequence while the cca2 gene product specifically adds the terminal adenosine residue thereby completing the CCA sequence. These data indicate that S. pombe represents the first eukaryote known to have separate CC- and A-adding activities for tRNA maturation and repair. In addition, we propose that a novel structural change in a tRNA nucleotidyltransferase is responsible for defining a CC-adding enzyme.     

Altered expression of plant lysyl tRNA synthetase promotes tRNA misacylation and translational recoding of lysine

The Arabidopsis thaliana lysyl tRNA synthetase (AtKRS) structurally and functionally resembles the well-characterized prokaryotic class IIb KRS, including the propensity to aminoacylate tRNA(Lys) with suboptimal identity elements, as well as non-cognate tRNAs. Transient expression of AtKRS in carrot cells promotes aminoacylation of such tRNAs in vivo and translational recoding of lysine at nonsense codons. Stable expression of AtKRS in Zea mays causes translational recoding of lysine into zeins, significantly enriching the lysine content of grain.     

Structural relationship between tRNA2 Lys and tRNA4 Lys from mouse lymphoma cells

Summary Mouse lymphoma cells have three major isoaccepting lysine tRNAs. Two of these isoacceptors, tRNA₂ ^Lys and tRNA₄ ^Lys, were sequenced by rapid gel or chromatogram readout methods. They have the same primary sequence but differ in two modified nucleotides. tRNA₄ ^Lys has an unmodified uridine replacing one dihydrouridine and an unidentified nucleotide, t⁶A^*, replacing t⁶A. This unidentified nucleotide is not a hypomodified form of t⁶A. Thus, tRNA4ys is not a simple precursor of tRNA₂ ^Lys. Both tRNAs have an unidentified nucleotide, U^**, in the third position of the anticodon. Also, partial sequences of minor homologs of tRNA₂ ^Lys and tRNA₄ ^Lys were obtained. The distinctions between tRNA₂ ^Lys and tRNA₄ ^Lys may be part of significant cellular roles as illustrated by the differential effects of these isoacceptors on the synthesis by lysyl-tRNA synthetase of diadenosine-5,5-P₁,P₄-tetraphosphate, a putative signal in DNA replication.     

Modified nucleotides in tRNA(Lys) and tRNA(Val) are important for translocation

Ribosomes translate genetic information encoded by messenger RNAs (mRNAs) into proteins. Accurate decoding by the ribosome depends on the proper interaction between the mRNA codon and the anticodon of transfer RNA (tRNA). tRNAs from all kingdoms of life are enzymatically modified at distinct sites, particularly in and near the anticodon. Yet, the role of these naturally occurring tRNA modifications in translation is not fully understood. Here we show that modified nucleosides at the first, or wobble, position of the anticodon and 3'-adjacent to the anticodon are important for translocation of tRNA from the ribosome's aminoacyl site (A site) to the peptidyl site (P site). Thus, naturally occurring modifications in tRNA contribute functional groups and conformational dynamics that are critical for accurate decoding of mRNA and for translocation to the P site during protein synthesis.     

The tRNA Recognition Mechanism of Folate/FAD-dependent tRNA Methyltransferase (TrmFO)

The conserved U54 in tRNA is often modified to 5-methyluridine (m⁵U) and forms a reverse Hoogsteen base pair with A58 that stabilizes the L-shaped tRNA structure. In Gram-positive and some Gram-negative eubacteria, m⁵U54 is produced by folate/FAD-dependent tRNA (m⁵U54) methyltransferase (TrmFO). TrmFO utilizes N⁵,N¹⁰-methylenetetrahydrofolate (CH₂THF) as a methyl donor. We previously reported an in vitro TrmFO assay system, in which unstable [¹⁴C]CH₂THF was supplied from [¹⁴C]serine and tetrahydrofolate by serine hydroxymethyltransferase. In the current study, we have improved the TrmFO assay system by optimization of enzyme and substrate concentrations and introduction of a filter assay system. Using this assay, we have focused on the tRNA recognition mechanism of TrmFO. 42 tRNA mutant variants were prepared, and experiments with truncated tRNA and microhelix RNAs revealed that the minimum requirement of TrmFO exists in the T-arm structure. The positive determinants for TrmFO were found to be the U54U55C56 sequence and G53-C61 base pair. The gel mobility shift assay and fluorescence quenching showed that the affinity of TrmFO for tRNA in the initial binding process is weak. The inhibition experiments showed that the methylated tRNA is released before the structural change process. Furthermore, we found that A38 prevents incorrect methylation of U32 in the anticodon loop. Moreover, the m¹A58 modification clearly accelerates the TrmFO reaction, suggesting a synergistic effect of the m⁵U54, m¹A58, and s²U54 modifications on m⁵s²U54 formation in Thermus thermophilus cells. The docking model of TrmFO and the T-arm showed that the G53-C61 base pair is not able to directly contact the enzyme.     

The anticodon and the D-domain sequences are essential determinants for plant cytosolic tRNA(Val) import into mitochondria

In higher plants, one-third to one-half of the mitochondrial tRNAs are encoded in the nucleus and are imported into mitochondria. This process appears to be highly specific for some tRNAs, but the factors that interact with tRNAs before and/or during import, as well as the signals present on the tRNAs, still need to be identified. The rare experiments performed so far suggest that, besides the probable implication of aminoacyl-tRNA synthetases, at least one additional import factor and/or structural features shared by imported tRNAs must be involved in plant mitochondrial tRNA import. To look for determinants that direct tRNA import into higher plant mitochondria, we have transformed BY2 tobacco cells with Arabidopsis thaliana cytosolic tRNA(Val)(AAC) carrying various mutations. The nucleotide replacements introduced in this naturally imported tRNA correspond to the anticodon and/or D-domain of the non-imported cytosolic tRNA(Met-e). Unlike the wild-type tRNA(Val)(AAC), a mutant tRNA(Val) carrying a methionine CAU anticodon that switches the aminoacylation of this tRNA from valine to methionine is not present in the mitochondrial fraction. Furthermore, mutant tRNAs(Val) carrying the D-domain of the tRNA(Met-e), although still efficiently recognized by the valyl-tRNA synthetase, are not imported any more into mitochondria. These data demonstrate that in plants, besides identity elements required for the recognition by the cognate aminoacyl-tRNA synthetase, tRNA molecules contain other determinants that are essential for mitochondrial import selectivity. Indeed, this suggests that the tRNA import mechanism occurring in plant mitochondria may be different from what has been described so far in yeast or in protozoa.     

Evolution of tRNA recognition systems and tRNA gene sequences

The aminoacylation of tRNAs by the aminoacyl-tRNA synthetases recapitulates the genetic code by dictating the association between amino acids and tRNA anticodons. The sequences of tRNAs were analyzed to investigate the nature of primordial recognition systems and to make inferences about the evolution of tRNA gene sequences and the evolution of the genetic code. Evidence is presented that primordial synthetases recognized acceptor stem nucleotides prior to the establishment of the three major phylogenetic lineages. However, acceptor stem sequences probably did not achieve a level of sequence diversity sufficient to faithfully specify the anticodon assignments of all 20 amino acids. This putative bottleneck in the evolution of the genetic code may have been alleviated by the advent of anticodon recognition. A phylogenetic analysis of tRNA gene sequences from the deep Archaea revealed groups that are united by sequence motifs which are located within a region of the tRNA that is involved in determining its tertiary structure. An association between the third anticodon nucleotide (N36) and these sequence motifs suggests that a tRNA-like structure existed close to the time that amino acid-anticodon assignments were being established. The sequence analysis also revealed that tRNA genes may evolve by anticodon mutations that recruit tRNAs from one isoaccepting group to another. Thus tRNA gene evolution may not always be monophyletic with respect to each isoaccepting group.Based on a presentation made at a workshop— Aminoacyl-tRNA Synthetases and the Evolution of the Genetic Code—held at Berkeley, CA, July 17–20, 1994 Correspondence to: M.E. Saks     

Overexpression of initiator methionine tRNA leads to global reprogramming of tRNA expression and increased proliferation in human epithelial cells

Transfer RNAs (tRNAs) are typically considered housekeeping products with little regulatory function. However, several studies over the past 10 years have linked tRNA misregulation to cancer. We have previously reported that tRNA levels are significantly elevated in breast cancer and multiple myeloma cells. To further investigate the cellular and physiological effects of tRNA overexpression, we overexpressed tRNA_i^Met in two human breast epithelial cell lines. We then determined tRNA abundance changes and performed phenotypic characterization. Overexpression of tRNA_i^Met significantly altered the global tRNA expression profile and resulted in increased cell metabolic activity and cell proliferation. Our results extend the relevance of tRNA overexpression in human cells and underscore the complexity of cellular regulation of tRNA expression.     

Distinct tRNA modifications in the thermo-acidophilic archaeon, Thermoplasma acidophilum

Thermoplasma acidophilum is a thermo-acidophilic archaeon. We purified tRNA^Leu (UAG) from T. acidophilum using a solid-phase DNA probe method and determined the RNA sequence after determining via nucleoside analysis and m⁷G-specific aniline cleavage because it has been reported that T. acidophilum tRNA contains m⁷G, which is generally not found in archaeal tRNAs. RNA sequencing and liquid chromatography–mass spectrometry revealed that the m⁷G modification exists at a novel position 49. Furthermore, we found several distinct modifications, which have not previously been found in archaeal tRNA, such as 4-thiouridine9, archaeosine13 and 5-carbamoylmethyuridine34. The related tRNA modification enzymes and their genes are discussed.     

Enzymatic mechanism of tRNA (mU54)methyltransferase

tRNA (m⁵U54)methyltransferase (RUMT) catalyzes the methylation of uridine 54 of transfer RNA by S-adenosyl-l-methionine. In this report, we present the enzymatic mechanism of RUMT, including the stereochemical course of the methylation reaction, and discuss RUMT-tRNA recognition. As part of its enzymatic mechanism, we postulate that RUMT catalyzes the disruption of RNA-RNA contacts. We also show that many nucleotide substitutions can be made in the T-loop of tRNA without affecting RUMT binding, indicating that the recognition of the T-loop by RUMT is not stringent.     

Knocking out a specific tRNA species within unfractionated Escherichia coli tRNA by using antisense (complementary) oligodeoxyribonucleotides

Methods for the preparation of an Escherichia coli tRNA mixture lacking one or a few specific tRNA species can be the basis for future applications of cell-free protein synthesis. We demonstrate here that virtually a single tRNA species in a crude E. coli tRNA mixture can be knocked out by an antisense (complementary) oligodeoxyribonucleotide. One out of five oligomers complementary to tRNA^Asp blocked the aspartylation almost completely, while minimally affecting the aminoacylation with other 13 amino acids tested. This `knockout' tRNA behaved similarly to the untreated tRNA in a cell-free translation of an mRNA lacking Asp codons.     

Classical molecular dynamics simulation of seryl tRNA synthetase and threonyl tRNA synthetase bound with tRNA and aminoacyl adenylate

Lacunae of understanding exist concerning the active site organization during the charging step of the aminoacylation reaction. We present here a molecular dynamics simulation study of the dynamics of the active site organization during charging step of subclass IIa dimeric SerRS from Thermus thermophilus (^ttSerRS) bound with ^tttRNA^Ser and dimeric ThrRS from Escherichia coli (^ecThrRS) bound with ^ectRNA^Thr. The interactions between the catalytically important loops and tRNA contribute to the change in dynamics of tRNA in free and bound states, respectively. These interactions help in the development of catalytically effective organization of the active site. The A76 end of the ^tttRNA^Ser exhibits fast dynamics in free State, which is significantly slowed down within the active site bound with adenylate. The loops change their conformation via multimodal dynamics (a slow diffusive mode of nanosecond time scale and fast librational mode of dynamics in picosecond time scale). The active site residues of the motif 2 loop approach the proximal bases of tRNA and adenylate by slow diffusive motion (in nanosecond time scale) and make conformational changes of the respective side chains via ultrafast librational motion to develop precise hydrogen bond geometry. Presence of bound Mg²⁺ ions around tRNA and dynamically slow bound water are other common features of both aaRSs. The presence of dynamically rigid Zinc ion coordination sphere and bipartite mode of recognition of ^ectRNA^Thr are observed.