Evidence for Late Resolution of the AUX Codon Box in Evolution

Recognition strategies for tRNA aminoacylation are ancient and highly conserved, having been selected very early in the evolution of the genetic code. In most cases, the trinucleotide anticodons of tRNA are important identity determinants for aminoacylation by cognate aminoacyl-tRNA synthetases. However, a degree of ambiguity exists in the recognition of certain tRNA^Ile isoacceptors that are initially transcribed with the methionine-specifying CAU anticodon. In most organisms, the C34 wobble position in these tRNA^Ile precursors is rapidly modified to lysidine to prevent recognition by methionyl-tRNA synthetase (MRS) and production of a chimeric Met-tRNA^Ile that would compromise translational fidelity. In certain bacteria, however, lysidine modification is not required for MRS rejection, indicating that this recognition strategy is not universally conserved and may be relatively recent. To explore the actual distribution of lysidine-dependent tRNA^Ile rejection by MRS, we have investigated the ability of bacterial MRSs from different clades to differentiate cognate tRNA_CAU^Met from near-cognate tRNA_CAU^Ile. Discrimination abilities vary greatly and appear unrelated to phylogenetic or structural features of the enzymes or sequence determinants of the tRNA. Our data indicate that tRNA^Ile identity elements were established late and independently in different bacterial groups. We propose that the observed variation in MRS discrimination ability reflects differences in the evolution of genetic code machineries of emerging bacterial clades.     

Modification of orthogonal tRNAs: unexpected consequences for sense codon reassignment

Breaking the degeneracy of the genetic code via sense codon reassignment has emerged as a way to incorporate multiple copies of multiple non-canonical amino acids into a protein of interest. Here, we report the modification of a normally orthogonal tRNA by a host enzyme and show that this adventitious modification has a direct impact on the activity of the orthogonal tRNA in translation. We observed nearly equal decoding of both histidine codons, CAU and CAC, by an engineered orthogonal M. jannaschii tRNA with an AUG anticodon: tRNA^Opt. We suspected a modification of the tRNA^Opt_AUG anticodon was responsible for the anomalous lack of codon discrimination and demonstrate that adenosine 34 of tRNA^Opt_AUG is converted to inosine. We identified tRNA^Opt_AUG anticodon loop variants that increase reassignment of the histidine CAU codon, decrease incorporation in response to the histidine CAC codon, and improve cell health and growth profiles. Recognizing tRNA modification as both a potential pitfall and avenue of directed alteration will be important as the field of genetic code engineering continues to infiltrate the genetic codes of diverse organisms.     

Sequence organization of the chloroplast ribosomal spacer ofSpinacia oleracea including the 3′ end of the 16S rRNA and the 5′ end of the 23S rRNA

The 2201-bp spacer between the chloroplast ribosomal 16S and 23S genes ofSpinacia oleracea was sequenced. It contains the genes of the tRNA^Ile (GAU) and tRNA^Ala (UGC) which are both interrupted by introns of respectively 728 and 816 bp. These introns belong to the class II according to the classfication of Michel and Dujon [17]. Comparison of the rDNA spacer sequence of maize, tobacco and spinach indicates that no conserved polypeptide is encoded within the introns of the two tRNA genes and that the two main insertions/deletions between the three plants are located within two loops of the class II introns secondary structure, which is therefore conserved. Based on the sequence complementarity observed between the upstream and downstream parts, of the 16S and 23S rRNA genes, RNase III-like secondary structures involved in the processing of the rRNA precursor are proposed.     

Rex1p deficiency leads to accumulation of precursor initiator tRNAMet and polyadenylation of substrate RNAs in Saccharomyces cerevisiae

A synthetic genetic array was used to identify lethal and slow-growth phenotypes produced when a mutation in TRM6, which encodes a tRNA modification enzyme subunit, was combined with the deletion of any non-essential gene in Saccharomyces cerevisiae. We found that deletion of the REX1 gene resulted in a slow-growth phenotype in the trm6-504 strain. Previously, REX1 was shown to be involved in processing the 3′ ends of 5S rRNA and the dimeric tRNA^Arg-tRNA^Asp. In this study, we have discovered a requirement for Rex1p in processing the 3′ end of tRNA_i^Met precursors and show that precursor tRNA_i^Met accumulates in a trm6-504 rex1Δ strain. Loss of Rex1p results in polyadenylation of its substrates, including tRNA_i^Met, suggesting that defects in 3′ end processing can activate the nuclear surveillance pathway. Finally, purified Rex1p displays Mg²⁺-dependent ribonuclease activity in vitro, and the enzyme is inactivated by mutation of two highly conserved amino acids.     

Position 34 of tRNA is a discriminative element for m5C38 modification by human DNMT2

Dnmt2, a member of the DNA methyltransferase superfamily, catalyzes the formation of 5-methylcytosine at position 38 in the anticodon loop of tRNAs. Dnmt2 regulates many cellular biological processes, especially the production of tRNA-derived fragments and intergenerational transmission of paternal metabolic disorders to offspring. Moreover, Dnmt2 is closely related to human cancers. The tRNA substrates of mammalian Dnmt2s are mainly detected using bisulfite sequencing; however, we lack supporting biochemical data concerning their substrate specificity or recognition mechanism. Here, we deciphered the tRNA substrates of human DNMT2 (hDNMT2) as tRNA^Asp(GUC), tRNA^Gly(GCC) and tRNA^Val(AAC). Intriguingly, for tRNA^Asp(GUC) and tRNA^Gly(GCC), G34 is the discriminator element; whereas for tRNA^Val(AAC), the inosine modification at position 34 (I34), which is formed by the ADAT2/3 complex, is the prerequisite for hDNMT2 recognition. We showed that the C³²U³³(G/I)³⁴N³⁵ (C/U)³⁶A³⁷C³⁸ motif in the anticodon loop, U11:A24 in the D stem, and the correct size of the variable loop are required for Dnmt2 recognition of substrate tRNAs. Furthermore, mammalian Dnmt2s possess a conserved tRNA recognition mechanism.     

N7-Methylguanine at position 46 (m7G46) in tRNA from Thermus thermophilus is required for cell viability at high temperatures through a tRNA modification network

N⁷-methylguanine at position 46 (m⁷G46) in tRNA is produced by tRNA (m⁷G46) methyltransferase (TrmB). To clarify the role of this modification, we made a trmB gene disruptant (ΔtrmB) of Thermus thermophilus, an extreme thermophilic eubacterium. The absence of TrmB activity in cell extract from the ΔtrmB strain and the lack of the m⁷G46 modification in tRNA^Phe were confirmed by enzyme assay, nucleoside analysis and RNA sequencing. When the ΔtrmB strain was cultured at high temperatures, several modified nucleotides in tRNA were hypo-modified in addition to the lack of the m⁷G46 modification. Assays with tRNA modification enzymes revealed hypo-modifications of Gm18 and m¹G37, suggesting that the m⁷G46 positively affects their formations. Although the lack of the m⁷G46 modification and the hypo-modifications do not affect the Phe charging activity of tRNA^Phe, they cause a decrease in melting temperature of class I tRNA and degradation of tRNA^Phe and tRNA^Ile. ³⁵S-Met incorporation into proteins revealed that protein synthesis in ΔtrmB cells is depressed above 70°C. At 80°C, the ΔtrmB strain exhibits a severe growth defect. Thus, the m⁷G46 modification is required for cell viability at high temperatures via a tRNA modification network, in which the m⁷G46 modification supports introduction of other modifications.     

Mitochondrial tRNA^Glu A14693G variant may modulate the phenotypic manifestation of deafness-associated 12S rRNA A1555G mutation in a Han Chinese family

Mutations in mitochondrial 12S rRNA gene are one of the most important causes of aminoglycoside-induced and nonsyndromic hearing loss. Here we report the characterization of one Han Chinese pedigree with aminoglycoside-induced and nonsyndromic hearing loss. This Chinese family carrying the 12S rRNA A1555G mutation exhibited high penetrance and expressivity of heating impairment. In particular, penetrances of hearing loss in this family pedigree were 43.8% and 25%, respectively, when aminoglycoside-induced heating loss was included or excluded. Mutational analysis of entire mitochondrial genomes in this family showed the homoplasmic A1555G mutation and a set of variants belonging to haplogroup Y2. Of these, the A14693G variant occurred at the extremely conserved nucleotide （conventional position 54） of the TψC-loop of tRNA^Clu and was absent in 156 Chinese controls. Nucleotides at position 54 of tRNAs are often modified, thereby contributing to the structural formation and stabilization of functional tRNAs. Thus, the structural alteration of tRNA by the A14693G variant may lead to a failure in tRNA metabolism and impair mitochondrial protein synthesis, thereby worsening mitochondrial dysfunctions altered by the A1555G mutation. Therefore, the tRNA^Glu A14693G variant may have a potential modifier role in increasing the penetrance and expressivity of the deafness-associated A1555G mutation in this Chinese pedigree.     

Commonality and diversity in tRNA substrate recognition in t6A biogenesis by eukaryotic KEOPSs

N ⁶-Threonylcarbamoyladenosine (t⁶A) is a universal and pivotal tRNA modification. KEOPS in eukaryotes participates in its biogenesis, whose mutations are connected with Galloway-Mowat syndrome. However, the tRNA substrate selection mechanism by KEOPS and t⁶A modification function in mammalian cells remain unclear. Here, we confirmed that all ANN-decoding human cytoplasmic tRNAs harbor a t⁶A moiety. Using t⁶A modification systems from various eukaryotes, we proposed the possible coevolution of position 33 of initiator tRNA^Met and modification enzymes. The role of the universal CCA end in t⁶A biogenesis varied among species. However, all KEOPSs critically depended on C32 and two base pairs in the D-stem. Knockdown of the catalytic subunit OSGEP in HEK293T cells had no effect on the steady-state abundance of cytoplasmic tRNAs but selectively inhibited tRNA^Ile aminoacylation. Combined with in vitro aminoacylation assays, we revealed that t⁶A functions as a tRNA^Ile isoacceptor-specific positive determinant for human cytoplasmic isoleucyl-tRNA synthetase (IARS1). t⁶A deficiency had divergent effects on decoding efficiency at ANN codons and promoted +1 frameshifting. Altogether, our results shed light on the tRNA recognition mechanism, revealing both commonality and diversity in substrate recognition by eukaryotic KEOPSs, and elucidated the critical role of t⁶A in tRNA^Ile aminoacylation and codon decoding in human cells.     

Crystal structure of glutamyl-queuosine tRNAAsp synthetase complexed with L-glutamate: structural elements mediating tRNA-independent activation of glutamate and glutamylation of tRNAAsp anticodon

Glutamyl-queuosine tRNA^Asp synthetase (Glu-Q-RS) from Escherichia coli is a paralog of the catalytic core of glutamyl-tRNA synthetase (GluRS) that catalyzes glutamylation of queuosine in the wobble position of tRNA^Asp. Despite important structural similarities, Glu-Q-RS and GluRS diverge strongly by their functional properties. The only feature common to both enzymes consists in the activation of Glu to form Glu-AMP, the intermediate of transfer RNA (tRNA) aminoacylation. However, both enzymes differ by the mechanism of selection of the cognate amino acid and by the mechanism of its activation. Whereas GluRS selects l-Glu and activates it only in the presence of the cognate tRNA^Glu, Glu-Q-RS forms Glu-AMP in the absence of tRNA. Moreover, while GluRS transfers the activated Glu to the 3′ accepting end of the cognate tRNA^Glu, Glu-Q-RS transfers the activated Glu to Q34 located in the anticodon loop of the noncognate tRNA^Asp. In order to gain insight into the structural elements leading to distinct mechanisms of amino acid activation, we solved the three-dimensional structure of Glu-Q-RS complexed to Glu and compared it to the structure of the GluRS·Glu complex. Comparison of the catalytic site of Glu-Q-RS with that of GluRS, combined with binding experiments of amino acids, shows that a restricted number of residues determine distinct catalytic properties of amino acid recognition and activation by the two enzymes. Furthermore, to explore the structural basis of the distinct aminoacylation properties of the two enzymes and to understand why Glu-Q-RS glutamylates only tRNA^Asp among the tRNAs possessing queuosine in position 34, we performed a tRNA mutational analysis to search for the elements of tRNA^Asp that determine recognition by Glu-Q-RS. The analyses made on tRNA^Asp and tRNA^Asn show that the presence of a C in position 38 is crucial for glutamylation of Q34. The results are discussed in the context of the evolution and adaptation of the tRNA glutamylation system.     

The tRNA discriminator base defines the mutual orthogonality of two distinct pyrrolysyl-tRNA synthetase/tRNAPyl pairs in the same organism

Site-specific incorporation of distinct non-canonical amino acids into proteins via genetic code expansion requires mutually orthogonal aminoacyl-tRNA synthetase/tRNA pairs. Pyrrolysyl-tRNA synthetase (PylRS)/tRNA^Pyl pairs are ideal for genetic code expansion and have been extensively engineered for developing mutually orthogonal pairs. Here, we identify two novel wild-type PylRS/tRNA^Pyl pairs simultaneously present in the deep-rooted extremely halophilic euryarchaeal methanogen Candidatus Methanohalarchaeum thermophilum HMET1, and show that both pairs are functional in the model halophilic archaeon Haloferax volcanii. These pairs consist of two different PylRS enzymes and two distinct tRNAs with dissimilar discriminator bases. Surprisingly, these two PylRS/tRNA^Pyl pairs display mutual orthogonality enabled by two unique features, the A73 discriminator base of tRNA^Pyl2 and a shorter motif 2 loop in PylRS2. In vivo translation experiments show that tRNA^Pyl2 charging by PylRS2 is defined by the enzyme''s shortened motif 2 loop. Finally, we demonstrate that the two HMET1 PylRS/tRNA^Pyl pairs can simultaneously decode UAG and UAA codons for incorporation of two distinct noncanonical amino acids into protein. This example of a single base change in a tRNA leading to additional coding capacity suggests that the growth of the genetic code is not yet limited by the number of identity elements fitting into the tRNA structure.     

RNA modifications stabilize the tertiary structure of tRNAfMet by locally increasing conformational dynamics

A plethora of modified nucleotides extends the chemical and conformational space for natural occurring RNAs. tRNAs constitute the class of RNAs with the highest modification rate. The extensive modification modulates their overall stability, the fidelity and efficiency of translation. However, the impact of nucleotide modifications on the local structural dynamics is not well characterized. Here we show that the incorporation of the modified nucleotides in tRNA^fMet from Escherichia coli leads to an increase in the local conformational dynamics, ultimately resulting in the stabilization of the overall tertiary structure. Through analysis of the local dynamics by NMR spectroscopic methods we find that, although the overall thermal stability of the tRNA is higher for the modified molecule, the conformational fluctuations on the local level are increased in comparison to an unmodified tRNA. In consequence, the melting of individual base pairs in the unmodified tRNA is determined by high entropic penalties compared to the modified. Further, we find that the modifications lead to a stabilization of long-range interactions harmonizing the stability of the tRNA’s secondary and tertiary structure. Our results demonstrate that the increase in chemical space through introduction of modifications enables the population of otherwise inaccessible conformational substates.     

Interaction of polyamines with fragments and whole molecules of yeast phenylalanine-specific transfer RNA

Binding of the polyamines spermidine (∼-+3) and spermine (∼-+4) to yeast tRNA^phe has been investigated by equilibrium dialysis under the same conditions used to study Mn²⁺-tRNA^phe interactions (Schreier & Schimmel, 1974). The polyamines bind to tRNA^phe in a co-operative and a non-co-operative phase, which is analogous to the behavior found with Mn²⁺. In the co-operative phase, the empirical index of co-operativity is somewhat greater for the polyamines, however. Binding constants for both the co-operative and non-co-operative phases are similar for Mn²⁺ and spermidine, and are strongest for spermine. Estimates of the total number of ligand binding sites indicate that these numbers are inversely proportional to the charge on the ligand for all three ligands. The interaction of polyamines with four large fragments of tRNA^phe shows no evidence for co-operativity. These results, together with recent kinetic studies, collectively suggest that polyamine binding to the co-operative sites is associated with tertiary structure formation and that polyamine and divalent metal ion interactions with tRNA occur by phenomenologically similar mechanisms, in spite of their structural diversity.     

Nucleotide sequences of transfer RNA genes in the Pisum sativum chloroplast DNA

Summary Eight transfer RNA (tRNA) genes which were previously mapped to five regions of the Pisum sativum (pea) chloroplast DNA (ctDNA) have been sequenced. They have been identified as tRNA^Val(GAC), tRNA^Asn(GUU), tRNA^Arg(ACG), tRNA^Leu(CAA), tRNA^Tyr(GUA), tRNA^Glu(UUC), tRNA^His(GUG), and tRNA^Arg(UCU) by their anticodons and by their similarity to other previously identified tRNA genes from the chloroplast DNAs of higher plants or from E. gracilis. In addition,two other tRNA genes, tRNA^Gly (UCC) and tRNA^Ile(GAU), have been partially sequenced. The tRNA genes are compared to other known chloroplast tRNA genes from higher plants and are found to be 90–100% homologous. In addition there are similarities in the overall arrangement of the individual genes between different plants. The 5 flanking regions and the internal sequences of tRNA genes have been studied for conserved regions and consensus sequences. Two unusual features have been found: there is an apparent intron in the D-loop of the tRNA^Gly(UCC), and the tRNA^Glu(UUC) contains GATTC in its T-loop.     

Structure of Escherichia coli Arginyl-tRNA Synthetase in Complex with tRNAArg: Pivotal Role of the D-loop

Aminoacyl-tRNA synthetases are essential components in protein biosynthesis. Arginyl-tRNA synthetase (ArgRS) belongs to the small group of aminoacyl-tRNA synthetases requiring cognate tRNA for amino acid activation. The crystal structure of Escherichia coli (Eco) ArgRS has been solved in complex with tRNA^Arg at 3.0-Å resolution. With this first bacterial tRNA complex, we are attempting to bridge the gap existing in structure–function understanding in prokaryotic tRNA^Arg recognition. The structure shows a tight binding of tRNA on the synthetase through the identity determinant A20 from the D-loop, a tRNA recognition snapshot never elucidated structurally. This interaction of A20 involves 5 amino acids from the synthetase. Additional contacts via U20a and U16 from the D-loop reinforce the interaction. The importance of D-loop recognition in EcoArgRS functioning is supported by a mutagenesis analysis of critical amino acids that anchor tRNA^Arg on the synthetase; in particular, mutations at amino acids interacting with A20 affect binding affinity to the tRNA and specificity of arginylation. Altogether the structural and functional data indicate that the unprecedented ArgRS crystal structure represents a snapshot during functioning and suggest that the recognition of the D-loop by ArgRS is an important trigger that anchors tRNA^Arg on the synthetase. In this process, A20 plays a major role, together with prominent conformational changes in several ArgRS domains that may eventually lead to the mature ArgRS:tRNA complex and the arginine activation. Functional implications that could be idiosyncratic to the arginine identity of bacterial ArgRSs are discussed.     

Genome-wide analysis revealed novel molecular features and evolution of Anti-codons in cyanobacterial tRNAs

Transfer RNAs (tRNAs) play important roles to decode the genetic information contained in mRNA in the process of translation. The tRNA molecules possess conserved nucleotides at specific position to regulate the unique function. However, several nucleotides at different position of the tRNA undergo modification to maintain proper stability and function. The major modifications include the presence of pseudouridine (Ψ) residue instead of uridine and the presence of m⁵-methylation sites. We found that, Ψ13 is conserved in D-stem, whereas Ψ38 & Ψ39 were conserved in the anti-codon loop (AL) and anti-codon arm (ACA), respectively. Furthermore, Ψ55 found to be conserved in the Ψ loop. Although, fourteen possible methylation sites can be found in the tRNA, cyanobacterial tRNAs were found to possess conserved G9, m³C₃₂, C₃₆, A₃₇, m⁵C₃₈ and U₅₄ methylation sites. The presence of multiple conserved methylation sites might be responsible for providing necessary stability to the tRNA. The evolutionary study revealed, tRNA^Met and tRNA^Ile were evolved earlier than other tRNA isotypes and their evolution is date back to at least 4000 million years ago. The presence of novel pseudouridination and m⁵-methylation sites in the cyanobacterial tRNAs are of particular interest for basic biology. Further experimental study can delineate their functional significance in protein translation.     

Dynamic modulation of Dnmt2-dependent tRNA methylation by the micronutrient queuine

Dnmt2 enzymes are cytosine-5 methyltransferases that methylate C38 of several tRNAs. We report here that the activities of two Dnmt2 homologs, Pmt1 from Schizosaccharomyces pombe and DnmA from Dictyostelium discoideum, are strongly stimulated by prior queuosine (Q) modification of the substrate tRNA. In vivo tRNA methylation levels were stimulated by growth of cells in queuine-containing medium; in vitro Pmt1 activity was enhanced on Q-containing RNA; and queuine-stimulated in vivo methylation was abrogated by the absence of the enzyme that inserts queuine into tRNA, eukaryotic tRNA-guanine transglycosylase. Global analysis of tRNA methylation in S. pombe showed a striking selectivity of Pmt1 for tRNA^Asp methylation, which distinguishes Pmt1 from other Dnmt2 homologs. The present analysis also revealed a novel Pmt1- and Q-independent tRNA methylation site in S. pombe, C34 of tRNA^Pro. Notably, queuine is a micronutrient that is scavenged by higher eukaryotes from the diet and gut microflora. This work therefore reveals an unanticipated route by which the environment can modulate tRNA modification in an organism.