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     

Compilation of tRNA sequences and sequences of tRNA genes.

Sequences of 3279 sequences of tRNA genes and tRNAs published up to December 1996 are included in the compilation. Alignment of the sequences, which is most compatible with the tRNA phylogeny and known three-dimensional structures of tRNA, is used. Sequences and references are available under http://www.uni-bayreuth. de/departments/biochemie/trna/     

Preparation of synthetic tRNA precursors with tRNA nucleotidyltransferase.

Rabbit liver tRNA nucleotidyltransferase can be used to substitute nucleotides within the -C-C-A sequence of tRNA or to add nucleotides following this sequence. These anomolous reactions of the enzyme have been used to prepare radioactively-labeled synthetic tRNA precursors which mimic the structure of the natural precursors. Under appropriate conditions synthetic precursors of defined structure can be made. In this paper we describe the synthesis of tRNA-C-[14C]U and tRNA-C-C-A-[14C]C-C, which are representative of tRNA precursors containing altered residues within the -C-C-A sequence or with extra residues following the normal 3'terminus. A variety of other possible precursors can also be prepared. These synthetic tRNA precursors have already proved useful for isolation of possible tRNA processing nucleases.     

tRNA turnaround

Two recently published papers (Takano et al., 2005 and Shaheen and Hopper, 2005) demonstrate that in S. cerevisiae, cytoplasmic tRNAs can be transported into the nucleus. This retrograde movement may expose mature tRNAs to nuclear proofreading or it may regulate tRNA availability in response to amino acid availability.     

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.     

The evolution of multi-isoacceptor tRNA families. Sequence of tRNA Leu CAA and tRNA Leu CAG from Anacystis nidulans

Two leucine tRNAs from the cyanophyte Anacystis nidulans have been isolated, and their complete nucleotide sequences have been determined by combining data from oligonucleotide fingerprints and sequencing gels. The two sequences are 87 nucleotides long, have the anticodons CAA and CAG, and differ from each other at a total of 28 positions. They have been compared to other known tRNA Leu sequences and incorporated into a phylogenetic tree comprising prokaryotic and chloroplastic tRNA Leu sequences. Mutations inferred from the tree show that some parts of the tRNA molecule are highly variable (the extra arm and the acceptor stem) while others are much more conserved (the D and T arms). The topology of the tree supports the idea that blue-green algae and chloroplasts share a common prokaryotic ancestor and show a basic divergence between XAA and XAG anticodon-containing tRNAs, suggesting that these two subfamilies result from an ancient gene duplication. Finally, comparison of this phylogenetic tree with those of other multi-isoacceptor tRNA families shows no common scheme, which may be due to independent refinement of codon-reading patterns in different tRNA families.     

The tRNA content of non-hemoglobinized red cell precursors: Evidence that tRNA content is controlled by tRNA utilization

The content of tRNA's accepting several amino acids was determined for the non-hemoglobinized early precursors of rabbit red cells and was compared with the tRNA content of rabbit reticulocytes and liver. The specialization of the tRNA content for hemoglobin synthesis seen in reticulocytes was not seen in the earlier precursors, suggesting that tRNA specialization does not occur before the onset of hemoglobin synthesis. The results favor hypotheses that the tRNA content develops in response to tRNA utilization in translation.     

Amino acid activation of a dual-specificity tRNA synthetase is independent of tRNA

Transfer RNA can play a role in amino acid activation by aminoacyl-tRNA synthetases. For the prolyl-tRNA synthetase (ProRS) of Methanococcus jannaschii, which activates both proline and cysteine, the role of tRNA in amino acid selection and activation is of interest in the effort to understand the mechanism of the dual-specificity. While activation of proline does not require tRNA, whether or not tRNA is required in the activation of cysteine has been a matter of debate. Here, investigation of a series of buffer conditions shows that activation of cysteine occurs without tRNA in a wide-range of buffers. However, the extent of cysteine activation is strongly buffer-dependent, varying over a 180-fold range. In contrast, the extent of proline activation is much less sensitive to buffer conditions, varying over only a 36-fold range. We also find that addition of tRNA has a small threefold stimulatory effect on cysteine activation. The lack of a major role of tRNA in activation of cysteine suggests that the dual-specificity enzyme must distinguish cysteine from proline directly, without the assistance of each cognate tRNA, to achieve the necessary specificity required for protein synthesis.