Conservation of a tRNA core for aminoacylation

The core region of Escherichia coli tRNA(Cys)is important for aminoacylation of the tRNA. This core contains an unusual G15:G48 base pair, and three adenosine nucleotides A13, A22 and A46 that are likely to form a 46:[13:22] adenosine base triple. We recently observed that the 15:48 base pair and the proposed 46:[13:22] triple are structurally and functionally coupled to contribute to aminoacylation. Inspection of a database of tRNA sequences shows that these elements are only found in one other tRNA, the Haemophilus influenzae tRNA(Cys). Because of the complexity of the core, conservation of sequence does not mean conservation of function. We here tested whether the conserved elements in H. influenzae tRNA(Cys)were also important for aminoacylation of H. influenzae tRNA(Cys). We cloned and purified a recombinant H. influenzae cysteine-tRNA synthe-tase and showed that it depends on 15:48 and 13, 22 and 46 in a relationship analogous to that of E. coli cysteine-tRNA synthetase. The functional conservation of the tRNA core is correlated with sequence conservation between E.coli and H.influenzae cysteine-tRNA synthetases. As the genome of H. influenzae is one of the smallest and may approximate a small autonomous entity in the development of life, the dependence of this genome on G15:G48 and its coupling with the proposed A46:[A13:A22] triple for aminoacylation with cysteine suggests an early role of these motifs in the evolution of decoding genetic information.     

The flexizyme system: a highly flexible tRNA aminoacylation tool for the translation apparatus

Flexizymes are de novo ribozymes capable of charging a wide variety of non-natural amino acids on tRNAs. The flexizyme system enables reprogramming of the genetic code by reassigning the codons that are generally assigned to natural amino acids to non-natural residues, and thus mRNA-directed synthesis of non-natural polypeptides can be achieved. In this review, we comprehensively summarize the history of the flexizyme system and its subsequent development into a practical tool. Furthermore, applications to the synthesis of novel biopolymers via genetic code reprogramming and perspectives for future applications are described.     

Alternative design of a tRNA core for aminoacylation

The core of Escherichia coli tRNA(Cys) is important for aminoacylation of the tRNA by cysteine-tRNA synthetase. This core differs from the common tRNA core by having a G15:G48, rather than a G15:C48 base-pair. Substitution of G15:G48 with G15:C48 decreases the catalytic efficiency of aminoacylation by two orders of magnitude. This indicates that the design of the core is not compatible with G15:C48. However, the core of E. coli tRNA(Gln), which contains G15:C48, is functional for cysteine-tRNA synthetase. Here, guided by the core of E. coli tRNA(Gln), we sought to test and identify alternative functional design of the tRNA(Cys) core that contains G15:C48. Although analysis of the crystal structure of tRNA(Cys) and tRNA(Gln) implicated long-range tertiary base-pairs above and below G15:G48 as important for a functional core, we showed that this was not the case. The replacement of tertiary interactions involving 9, 21, and 59 in tRNA(Cys) with those in tRNA(Gln) did not construct a functional core that contained G15:C48. In contrast, substitution of nucleotides in the variable loop adjacent to 48 of the 15:48 base-pair created functional cores. Modeling studies of a functional core suggests that the re-constructed core arose from enhanced stacking interactions that compensated for the disruption caused by the G15:C48 base-pair. The repacked tRNA core displayed features that were distinct from those of the wild-type and provided evidence that stacking interactions are alternative means than long-range tertiary base-pairs to a functional core for aminoacylation.     

Indirect readout of tRNA for aminoacylation

Aminoacylation of tRNA by aminoacyl-tRNA synthetases is the essential reaction that matches protein amino acids with the trinucleotide sequences specified in mRNA. Direct electrostatic interactions made by tRNA synthetases with discriminating functional groups on the tRNA bases have long been known to determine aminoacylation specificity. However, structural and biochemical studies have revealed a second "indirect readout" mechanism that makes an important contribution as well. In indirect readout, the sequence-dependent conformations of tRNA are recognized through protein contacts with the sugar-phosphate backbone and with nonspecific portions of the bases. This mechanism appears to function in single-stranded regions, in canonical A-type duplex segments, and in the complex tertiary core portion of the tRNA. Operation of the indirect mechanism is not exclusive of the direct mechanism, and both are further mediated by induced-fit rearrangements, in which enzyme and tRNA undergo precise conformational changes after formation of an initial encounter complex. The examples of indirect readout in tRNA synthetase complexes extend the concept beyond its traditional application to DNA duplexes and serve as models for the operation of this mechanism in more complex systems such as the ribosome.     

Identity elements for specific aminoacylation of a tRNA by mammalian lysyl-tRNA synthetase bearing a nonspecific tRNA-interacting factor

Mammalian lysyl-tRNA synthetase (LysRS) has an N-terminal polypeptide chain extension appended to a prokaryotic-like synthetase domain. This extension, termed a tRNA-interacting factor (tIF), possesses a RNA-binding motif [KxxxK(K/R)xxK] that binds nonspecifically the acceptor TPsiC stem-loop domain of tRNA and provides a potent tRNA binding capacity to this enzyme. Consequently, native LysRS aminoacylates a RNA minihelix mimicking the amino acid acceptor stem-loop domain of tRNA(3)(Lys). Here, examination of minihelix recognition showed that mammalian LysRS aminoacylates RNA minihelices without specificity of sequence, revealing that none of the nucleotides from the acceptor TPsiC stem-loop domain are essential determinants of tRNA(Lys) acceptor identity. To test whether the tIF domain reduces the specificity of the synthetase with regard to complete tRNA molecules, aminoacylation of wild-type and mutant noncognate tRNAs by wild-type or N-terminally truncated LysRS was examined. The presence of the UUU anticodon of tRNA(Lys) appeared to be necessary and sufficient to transform yeast tRNA(Asp) or tRNA(i)(Met) into potent lysine acceptor tRNAs. Thus, nonspecific RNA-protein interactions between the acceptor stem of tRNA and the tIF domain do not relax the tRNA specificity of mammalian LysRS. The possibility that interaction of the full-length cognate tRNA with the synthetase is required to induce the catalytic center of the enzyme into a productive conformation is discussed.     

The structural elements responsible for contraction in the ciliateSpirostomum

Summary The surface of the contractile ciliateSpirostomum contains continuous spiral ciliated grooves traversing its length. Bundles of microtubules run parallel to the base of the grooves and appear to be part of a cohesive, semi-rigid cortex. Beneath this, a network of microfilament bundles occurs which is attached to the peristomal membranelle apparatus, also part of the cortex. The possible roles played by these structures during contraction of the organism were examined.During contraction, the entire cortex twists and the spiral arrangement of the grooves and microtubules decreases in pitch and increases in diameter. Simultaneously, the bundles of microfilaments change in distribution and appearance so as to suggest that they are undergoing an active shortening process. Based on these observations, two models for contraction are presented. In one, shortening of the animal arises from a smooth muscle-like contraction of the microfilament network whose attachment to the basal bodies of the membranellar cilia guarantees shortening and widening of the cortex and consequently the whole animal. In the second, a shortening (or sliding) of external microtubules relative to internal ones in the cortical microtubule bundles would result in an increase in diameter, a decrease in pitch, and a decrease in axial length of the bundles, resulting in contraction of the animal. The observations do not allow a choice between these alternatives to be made, and they may not, in fact, be mutually exclusive.     

Effect of aminoacylation on tRNA conformation

Translational diffusion coefficients have been simulated for various conformations of tRNA^Phe (yeast) by bead models, in order to analyze data obtained by dynamic light scattering on the free and the aminoacylated form. The 18% increase of the translational diffusion coefficient upon deacylation, reported by Potts et al. (1981), could not be represented by any change of the L-hinge angle, but could only be simulated by a conformation change to an extended form with extensive dissociation of base pairs. Since extensive unpairing is not consistent with evidence accumulated in the literature, the change of the diffusion coefficient must be mainly due to processes other than intramolecular conformational changes.     

A new assay for tRNA aminoacylation kinetics.

An improved quantitative assay for tRNA aminoacylation is presented based on charging of a nicked tRNA followed by separation of an aminoacylated 3'-fragment on an acidic denaturing polyacrylamide gel. Kinetic parameters of tRNA aminoacylation by Escherichia coli AlaRS obtained by the new method are in excellent agreement with those measured by the conventional method. This assay provides several advantages over the traditional methods of measuring tRNA aminoacylation: (1) the fraction of aminoacyl-tRNA is measured directly; (2) data can be obtained at saturating amino acid concentrations; and (3) the assay is significantly more sensitive.     

Inhibition of selenocysteine tRNA[Ser]Sec aminoacylation provides evidence that aminoacylation is required for regulatory methylation of this tRNA

GDP dissociation inhibitor (GDI) plays an essential role in regulating the state of bound nucleotides and subcellular localizations of Rab proteins. In our previous study, we showed that OsGDI3 facilitates the recycling of OsRab11 with a help of OsGAP1. In this study, we show that OsGDI3 complement the yeast sec19-1 mutant, a temperature-sensitive allele of the yeast GDI gene, suggesting that OsGDI3 is a functional ortholog of yeast GDI. To obtain further knowledge on the function of OsGDI3, candidate OsGDI3-interacting proteins were identified by yeast two-hybrid screens. OsMAPK2 is one of OsGDI3 interacting proteins from yeast two-hybrid screens and subject to further analysis. A kinase assay showed that the autophosphorylation activity of OsMAPK2 is inhibited by OsGDI3 in vitro. In addition, ectopic expressions of OsGDI3-in Arabidopsis cause reductions at the level of phosphorylated AtMPK in phosphorylation activity. Taken together, OsGDI3 functions as a negative regulator of OsMAPK2 through modulating its kinase activity.     

Interdomain communication between weak structural elements within a disease-related human tRNA

The structure of the human mitochondrial (hs mt) tRNALeu(UUR) features several domains that are predicted to exhibit limited thermodynamic stability. An elevated frequency of disease-related mutations within these domains suggests a link between structural instability and the functional effects of pathogenic mutations. A series of tRNAs featuring mutations within the D and anticodon stems were prepared and investigated using nuclease probing. Structural mapping studies indicated that these domains were partially denatured for the wild type (WT) hs mt tRNALeu(UUR) and were significantly stabilized by mutations introducing additional or stronger base pairs into the stem regions. In addition, trends in the aminoacylation activities of the D stem mutants suggested that the loose structure is required for function, with mutants displaying the most ordered structures exhibiting the lowest levels of aminoacylation activity. A pronounced interdependence of the structures of the anticodon and D stems was observed, with mutations strengthening the D stem stabilizing the anticodon stem and vice versa. The existence of strong interdomain communication was further elucidated with a mutant of hs mt tRNALeu(UUR) containing a stabilized D stem and a pathogenic mutation that disrupted the anticodon stem. Strengthening the structure of the D stem completely restored the function of the disease-related mutant to WT levels, indicating that propagated structural weaknesses contribute to the functional deactivation of this tRNA by mutations.     

Acquisition of an insertion peptide for efficient aminoacylation by a halophile tRNA synthetase

Enzymes of halophilic organisms contain unusual peptide motifs that are absent from their mesophilic counterparts. The functions of these halophile-specific peptides are largely unknown. Here we have identified an unusual peptide that is unique to several halophile archaeal cysteinyl-tRNA synthetases (CysRS), which catalyze attachment of cysteine to tRNA(Cys) to generate the essential cysteinyl-tRNA(Cys) required for protein synthesis. This peptide is located near the active site in the catalytic domain and is highly enriched with acidic residues. In the CysRS of the extreme halophile Halobacterium species NRC-1, deletion of the peptide reduces the catalytic efficiency of aminoacylation by a factor of 100 that largely results from a defect in kcat, rather than the Km for tRNA(Cys). In contrast, maintaining the peptide length but substituting acidic residues in the peptide with neutral or basic residues has no major deleterious effect, suggesting that the acidity of the peptide is not important for the kcat of tRNA aminoacylation. Analysis of general protein structure under physiological high salt concentrations, by circular dichroism and by fluorescence titration of tRNA binding, indicates little change due to deletion of the peptide. However, the presence of the peptide confers tolerance to lower salt levels, and fluorescence analysis in 30% sucrose reveals instability of the enzyme without the peptide. We suggest that the stability associated with the peptide can be used to promote proper enzyme conformation transitions in various stages of tRNA aminoacylation that are associated with catalysis. The acquisition of the peptide by the halophilic CysRS suggests an enzyme adaptation to high salinity.     

Evidence for a conserved relationship between an acceptor stem and a tRNA for aminoacylation.

The anticodon-independent aminoacylation of RNA hairpin helices that reconstruct tRNA acceptor stems has been demonstrated for at least 10 aminoacyl-tRNA synthetases. For Escherichia coli cysteine tRNA synthetase, the specificity of aminoacylation of the acceptor stem is determined by the U73 nucleotide adjacent to the amino acid attachment site. Because U73 is present in all known cysteine tRNAs, we investigated the ability of the E. coli cystein enzyme to aminoacylate a heterologous acceptor stem. We show here that a minihelixCys based on the acceptor-T psi C stem of yeast tRNACys is a substrate for the E. coli enzyme, and that aminoacylation of this minihelix is dependent on U73. Additionally, we identify two base pairs in the acceptor stem that quantitatively convert the E. coli acceptor stem to the yeast acceptor stem. The influence of U73 and these two base pairs is completely retained in the full-length tRNA. This suggests a conserved relationship between the acceptor stem alone and the acceptor stem in the context of a tRNA for aminoacylation with cysteine. However, the primary determinant in the species-specific aminoacylation of the E. coli and yeast cysteine tRNAs is a tertiary base pair at position 15:48 outside of the acceptor stem. Although E. coli tRNACys has an unusual G15:G48 tertiary base pair, yeast tRNACys has a more common G15:C48 that prevents efficient aminoacylation of yeast tRNACys by the E. coli enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)