RNA binding determinant in some class I tRNA synthetases identified by alignment-guided mutagenesis.

The N-terminal nucleotide binding folds of all 10 class I tRNA synthetases (RSs) contain characteristic conserved sequence motifs that define this class of synthetases. Sequences of C-terminal domains, which in some cases are known to interact with anticodons, are divergent. In the 676-amino acid Escherichia coli methionyl-tRNA synthetase (MetRS), interactions with the methionine tRNA anticodon are sensitive to substitutions at a specific location on the surface of the C-terminal domain of this protein of known three-dimensional structure. Although four class I synthetases of heterogeneous lengths and unknown structures are believed to be historically related to MetRS, pair-wise sequence similarities in the region of this RNA binding determinant are obscure. A multiple alignment of all sequences of three of these synthetases with all MetRS sequences suggested a location for the functional analog of the anticodon-binding site in these enzymes. We chose a member of this set for alignment-guided mutagenesis, combined with a functional analysis of mutant proteins. Substitutions within two amino acids of the site fixed by the multiple sequence alignment severely affected interactions with tRNA but not with ATP or amino acid. Multiple individual replacements at this location do not disrupt enzyme stability, indicating this segment is on the surface, as in the MetRS structure. The results suggest the location of an RNA binding determinant in each of these three synthetases of unknown structure.     

Selection of suppressor methionyl-tRNA synthetases: mapping the tRNA anticodon binding site.

Accurate aminoacylation of a tRNA by Escherichia coli methionyl-tRNA synthetase (MTS) is specified by the CAU anticodon. A genetic screening procedure was designed to isolate MTS mutants able to aminoacylate a methionine amber tRNA (CUA anticodon). Selected suppressor MTS enzymes all possess one or several mutations in the vicinity of Trp-461, a residue that is the major contributor to the stability of complexes formed with tRNAs having the cognate CAU anticodon. Analysis of catalytic properties of purified suppressor enzymes shows that they have acquired an additional specificity toward the amber anticodon without complete disruption of the methionine anticodon site. It is concluded that both positive and negative discrimination toward the binding of tRNA anticodon sequences is restricted to a limited region of the synthetase, residues 451-467.     

A single gene of chloroplast origin codes for mitochondrial and chloroplastic methionyl–tRNA synthetase in Arabidopsis thaliana

One-fifth of the tRNAs used in plant mitochondrial translation is coded for by chloroplast-derived tRNA genes. To understand how aminoacyl–tRNA synthetases have adapted to the presence of these tRNAs in mitochondria, we have cloned an Arabidopsis thaliana cDNA coding for a methionyl–tRNA synthetase. This enzyme was chosen because chloroplast-like elongator tRNA^Met genes have been described in several plant species, including A. thaliana. We demonstrate here that the isolated cDNA codes for both the chloroplastic and the mitochondrial methionyl–tRNA synthetase (MetRS). The protein is transported into isolated chloroplasts and mitochondria and is processed to its mature form in both organelles. Transient expression assays using the green fluorescent protein demonstrated that the N-terminal region of the MetRS is sufficient to address the protein to both chloroplasts and mitochondria. Moreover, characterization of MetRS activities from mitochondria and chloroplasts of pea showed that only one MetRS activity exists in each organelle and that both are indistinguishable by their behavior on ion exchange and hydrophobic chromatographies. The high degree of sequence similarity between A. thaliana and Synechocystis MetRS strongly suggests that the A. thaliana MetRS gene described here is of chloroplast origin.     

Visualization of elongation factor G on the Escherichia coli 70S ribosome: The mechanism of translocation

During protein synthesis, elongation factor G (EF-G) binds to the ribosome and promotes the step of translocation, a process in which tRNA moves from the A to the P site of the ribosome and the mRNA is advanced by one codon. By using three-dimensional cryo-electron microscopy, we have visualized EF-G in a ribosome–EF-G–GDP–fusidic acid complex. Fitting the crystal structure of EF-G–GDP into the cryo density map reveals a large conformational change mainly associated with domain IV, the domain that mimics the shape of the anticodon arm of the tRNA in the structurally homologous ternary complex of Phe-tRNA^Phe, EF-Tu, and a GTP analog. The tip portion of this domain is found in a position that overlaps the anticodon arm of the A-site tRNA, whose position in the ribosome is known from a study of the pretranslocational complex, implying that EF-G displaces the A-site tRNA to the P site by physical interaction with the anticodon arm.     

Hydroxyl radical cleavage of tRNA in the ribosomal P site.

Hydroxyl radical is a useful probe of the accessibility of the sugar moiety of nucleic acids to solvent. Here we compare the accessibility of free and ribosome-bound yeast tRNA(Phe), Escherichia coli tRNA(Phe), and E. coli tRNA(Leu2) to attack by hydroxyl radicals generated from Fe(2+)-EDTA. When bound to the P site of 30S ribosomal subunits, a discrete region, corresponding almost precisely to the anticodon stem-loop, is strongly protected; weaker protection is observed in the 3' strand of the D stem and in the variable loop. The protected nucleotides constitute a well-defined substructure, corresponding to the lower half of the anticodon-D loop coaxial arm of the tRNA crystal structure. This result suggests that the 30S P site contains a pocket that becomes inaccessible to the Fe(2+)-EDTA complex when tRNA is bound, whose minimum dimensions can be inferred from the boundaries of the protected region of tRNA. When bound to the P site of 70S ribosomes, the entire tRNA backbone becomes inaccessible to hydroxyl radicals. Since previous studies have shown that virtually the entire footprint of a P-site tRNA on 16S and 23S rRNAs is mimicked by the extremities of the tRNA (the anticodon stem-loop plus the 3'-terminal aminoacyl-pentanucleotide), protection of the entire tRNA was unexpected. We conclude that protection of the elbow of tRNA is due either to interactions with ribosomal proteins or to enclosure in an inaccessible site formed by association of the two ribosomal subunits.     

The anticodon triplet is not sufficient to confer methionine acceptance to a transfer RNA.

Previous work suggested that the presence of the anticodon CAU alone was enough to confer methionine acceptance to a tRNA. Conversions of Escherichia coli nonmethionine tRNAs to a methionine-accepting species were obtained by substitutions reconstructing the whole methionine anticodon loop together with preservation (or introduction) of the acceptor stem base A73. We show here that the CAU triplet alone is unable to confer methionine acceptance when transplanted into a yeast aspartic tRNA. Both non-anticodon bases of the anticodon loop of yeast tRNA(Met) and A73 are required in addition to CAU for methionine acceptance. The importance of these non-anticodon bases in other CAU-containing tRNA frameworks was also established. These specific non-anticodon base interactions make a substantial thermodynamic contribution to the methionine acceptance of a transfer RNA.     

Construction of a composite tRNA gene by anticodon loop transplant.

By using sites for the restriction nuclease Hpa II, the information for the anticodon stem and loop of an altered Su+2 amber suppressor tRNA (a mutant of tRNAGln) has been transplanted to a specially prepared tRNATrp gene, which lacks it homologous anticodon stem and loop sequence. The resulting tRNA gene was cloned under lac operator-promoter control. The result is a functional, hybrid, amber-suppressor tRNA that can exhibit a moderately high efficiency in translation. It appears less efficient, however, than Su+7 tRNA, the amber suppressor that results from a direct anticodon mutation in tRNATrp. As judged by its suppressor spectrum, which is almost identical to the spectra of Su+2, and Su+7, the recomposed tRNA inserts glutamine at amber sites. This experiment is the prototype of a series of construction that examine the role of the nucleotides in the anticodon region.     

The importance of tRNA backbone-mediated interactions with synthetase for aminoacylation

We have identified six new aminoacylation determinants of Escherichia coli tRNA^Gln in a genetic and biochemical analysis of suppressor tRNA. The new determinants occupy the interior of the acceptor stem, the inside corner of the L shape, and the anticodon loop of the molecule. They supplement the primary determinants located in the anticodon and acceptor end of tRNA^Gln described previously. Remarkably, the three-dimensional structure of the complex between tRNA^Gln and glutaminyl-tRNA synthetase shows that the enzyme interacts with the phosphate–sugar backbone but not the base of every new determinant. Moreover, a small protein motif interacts with five of these determinants, and it binds proximal to the sixth. The motif also interacts with the middle base of the anticodon and with the backbones of six other nucleotides. Our results emphasize that synthetase recognition of tRNA is more elaborate than amino acid side chains of the enzyme interacting with nucleotide bases of the tRNA. Recognition also includes synthetase interaction with tRNA backbone functionalities whose distinctive locations in three-dimensional space are exquisitely determined by the tRNA sequence.     

Enzymatic aminoacylation of sequence-specific RNA minihelices and hybrid duplexes with methionine.

RNA hairpin helices whose sequences are based on the acceptor stems of alanine and histidine tRNAs are specifically aminoacylated with their cognate amino acids. In these examples, major determinants for the identities of the respective tRNAs reside in the acceptor stem; the anticodon and other parts of the tRNA are dispensable for aminoacylation. In contrast, the anticodon is a major determinant for the identity of a methionine tRNA. RNA hairpin helices and hybrid duplexes that reconstruct the acceptor-T psi C stem and the acceptor stem, respectively, of methionine tRNA were investigated here for aminoacylation with methionine. Direct visualization of the aminoacylated RNA product on an acidic polyacrylamide gel by phosphor imaging demonstrated specific aminoacylation with substrates that contained as few as 7 base pairs. No aminoacylation with methionine was detected with several analogous RNA substrates whose sequences were based on noncognate tRNAs. While the efficiency of aminoacylation is reduced by orders of magnitude relative to methionine tRNA, the results establish that specific aminoacylation with methionine of small duplex substrates can be achieved without the anticodon or other domains of the tRNA. The results, combined with earlier studies, suggest a highly specific adaptation of the structures of aminoacyl-tRNA synthetases to the acceptor stems of their cognate tRNAs, resulting in a relationship between the nucleotide sequences/structures of small RNA duplexes and specific amino acids.     

From elongator tRNA to initiator tRNA.

We show that the two most important properties needed for a tRNA to function in initiation in Escherichia coli are its ability to be formylated and its ability to bind to the ribosomal P site. This conclusion is based on conversion of two different elongator tRNAs to ones that can act as initiators in E. coli. We transplanted the features unique to E. coli and eubacterial initiator tRNAs to E. coli elongator methionine tRNA (tRNA(Met)) along with an anticodon sequence change and analyzed their activities in initiation in E. coli. Introduction of a C1.A72 mismatch at the end of the acceptor stem of tRNA(Met), which generates the minimal features necessary for formylation, produces a tRNA with very low activity in initiation. Subsequent introduction of three consecutive G.C base pairs at the bottom of the anticodon stem, which is necessary for ribosomal P site binding, produces a tRNA with significant activity in initiation. Furthermore, introduction of the features necessary for formylation and for ribosomal P site binding into E. coli elongator glutamine tRNA produces a tRNA that initiates protein synthesis in E. coli.     

Pleiotropy of hisT Mutants Blocked in Pseudouridine Synthesis in tRNA: Leucine and Isoleucine-V aline Operons

The hisT gene codes for an enzyme responsible for the conversion of uridine to pseudouridine (Psi) in the anticodon region of many tRNA species in Salmonella typhimurium. We have previously shown that a hisT mutant has tRNA(His) which lacks pseudouridine in this region and as a consequence has an altered chromatographic behavior. We show here a similar alteration in chromatographic behavior of all tRNA(Leu) and one tRNA(Ile) species from a hisT mutant. By contrast, tRNA(Val), which contains no pseudouridine except for the one in the TPsiCG sequence, is chromatographically unaltered in a hisT mutant.The absence of pseudouridine in the anticodon region of tRNA in hisT mutants has been previously shown to cause derepression of the histidine operon. We show here that in hisT mutants the regulation of the leucine and the isoleucine and valine operons is also affected: the enzymes of these operons are refractory to repression by the branched chain amino acids. However, there is no difference between hisT and wild type in the pattern of derepression caused by isoleucine or valine limitation and only a slight difference in the enzyme levels in cells grown on minimal medium.The alteration in the regulation of branched chain amino acid operons may also explain why hisT mutants are resistant to inhibition of growth by the amino acid analogues 5,5,5-trifluoroleucine, beta-hydroxyleucine, and norleucine and by the oligopeptides glycylglycylnorleucine and norleucylnorleucine.     

Dynamical networks in tRNA:protein complexes

Community network analysis derived from molecular dynamics simulations is used to identify and compare the signaling pathways in a bacterial glutamyl-tRNA synthetase (GluRS):tRNA^Glu and an archaeal leucyl-tRNA synthetase (LeuRS):tRNA^Leu complex. Although the 2 class I synthetases have remarkably different interactions with their cognate tRNAs, the allosteric networks for charging tRNA with the correct amino acid display considerable similarities. A dynamic contact map defines the edges connecting nodes (amino acids and nucleotides) in the physical network whose overall topology is presented as a network of communities, local substructures that are highly intraconnected, but loosely interconnected. Whereas nodes within a single community can communicate through many alternate pathways, the communication between monomers in different communities has to take place through a smaller number of critical edges or interactions. Consistent with this analysis, there are a large number of suboptimal paths that can be used for communication between the identity elements on the tRNAs and the catalytic site in the aaRS:tRNA complexes. Residues and nucleotides in the majority of pathways for intercommunity signal transmission are evolutionarily conserved and are predicted to be important for allosteric signaling. The same monomers are also found in a majority of the suboptimal paths. Modifying these residues or nucleotides has a large effect on the communication pathways in the protein:RNA complex consistent with kinetic data.     

Site-selective cleavage of structured RNA by a staphylococcal nuclease-DNA hybrid.

A hybrid enzyme consisting of an oligodeoxyribonucleotide fused to a unique site on staphylococcal nuclease site-selectively cleaves a number of natural RNAs including Escherichia coli M1 RNA (377 bases), 16S rRNA (1542 bases), and yeast tRNA(Phe). The oligonucleotide directs the nuclease activity of the enzyme to the nucleotides directly adjacent to the complementary target sequence on the substrate RNA. In the case of M1 RNA, hydrolysis occurs primarily at one phosphodiester bond, converting 50% of the starting material to product. Furthermore, the reaction products can be enzymatically manipulated: tRNA(Phe) was cleaved in the anticodon region and was religated to form the full-length tRNA in high yield. Because the specificity of these hybrid enzymes can be easily altered, they should prove to be useful tools for probing RNA structure and function.     

Escherichia coli formylmethionine tRNA: mutations in GGGCCC sequence conserved in anticodon stem of initiator tRNAs affect initiation of protein synthesis and conformation of anticodon loop.

We have generated mutants of Escherichia coli formylmethionine initiator tRNA in which one, two, and all three G X C base pairs in the GGGCCC sequence in the anticodon stem are changed to those found in E. coli elongator methionine tRNA. Overproduction of the mutant tRNAs using M13 recombinants as an expression vector and development of a one-step purification scheme allowed us to purify, characterize, and analyze the function of the mutant tRNAs. After aminoacylation and formylation, the function of mutant formylmethionyl tRNAs was analyzed in an MS2 RNA-directed in vitro protein-synthesizing system, in AUG-dependent ribosomal P site binding, and in initiation factor binding. The mutant tRNAs show progressive loss of activity in initiation, the mutant with all three G X C base pairs substituted being the least active. The mutations affect binding to the ribosomal P site. None of the mutations affects binding to initiation factor 2. We also show that there is a progressive increase in accessibility of phosphodiester bonds in the anticodon loop of the three mutants to S1 nuclease, such that the cleavage pattern of the mutant with all three G X C base-pair changes resembles that of elongator tRNAs. These results are consistent with the notion that the contiguous G X C base pairs in the anticodon stem of initiator tRNAs impart on the anticodon loop a unique conformation, which may be important in targeting the initiator tRNA to the ribosomal P site during initiation of protein synthesis.     

Localization of the decoding region on the 30S Escherichia coli ribosomal subunit by affinity immunoelectron microscopy.

The decoding region of the Escherichia coli ribosome has been localized by affinity immunoelectron microscopy. Valyl-tRNA1Val, derivatized at the alpha-amino end with the dinitrophenyl group, was bound to the ribosomal P site of 70S ribosomes and crosslinked specifically to 16S RNA by 310- to 325-nm irradiation. Previous work has shown that crosslink occurs between the 5' anticodon base of the tRNA and a pyrimidine in the 3' one-third of the 16S RNA. By reaction of the dinitrophenyl group with antibody, dimers of the 30S tRNA covalent complexes were prepared containing one covalently attached tRNA per 30S subunit. Electron microscopic visualization of the antibody attached to the dinitrophenyl group located the position of the 3' end of the tRNA. Several sites, with a strong preference for the large protrusion or cleft region in the upper one-third of the subunit, were found. The multiplicity of sites is likely due to the freedom of orientation of the 3' end of the tRNA which is approximately 80 A from the site of crosslinking. By extrapolating this distance from each of the antigenic sites, we concluded that the anticodon of tRNA when in the P site is probably located in the cleft region of the 30S subunit.     

Codon recognition rules in yeast mitochondria.

The mitochondrial genome of Saccharomyces cerevisiae codes for 24 tRNAs. The nucleotide sequences of the tRNA genes suggest a unique set of rules that govern the decoding of the mitochondrial genetic code. The four codons of unmixed fmilies are recognized by single tRNAs that always have a U in the wobble position of the anticodon. The codons of the mixed families are read by two different tRNAs. Codons terminating in a C or U are recognized by tRNAs with a G and codons terminating in a G or A are recognized by tRNAs with a U in the corresponding positions of the anticodons. There are two exceptions to these rules. In the AUN family for isoleucine and methionine, the isoleucine tRNA has a G and the methionine tRNA has a C in the wobble position. The tRNA for the arginine CGN family also has an A in the wobble position of the anticodon. It is of interest that the CGN codons have not been found in the mitochondrial genes sequenced to date. The simplified decoding system of yeast mitochondria allows all the codons to be recognized by only 24 tRNAs.     

Anticodon-dependent aminoacylation of a noncognate tRNA with isoleucine, valine, and phenylalanine in vivo.

An assay based on the initiation of protein synthesis in Escherichia coli has been used to explore the role of the anticodon in tRNA identity in vivo. Mutations were introduced into the initiator tRNA to change the wild-type anticodon from CAU (methionine) to GAU (isoleucine), GAC (valine), and GAA (phenylalanine), where each derivative differs from the preceding by a single base change in the anticodon (underlined). These changes were sufficient to cause the mutant tRNAs to be aminoacylated by the corresponding aminoacyl-tRNA synthetases based on the amino acid inserted into protein from complementary initiation codons. Construction of additional single base anticodon variants (GUU, GGU, GCC, GUC, GCA, and UAA) showed that all three anticodon bases specify isoleucine and phenylalanine identity and that both the middle and the third anticodon bases are important for valine identity in vivo.     

Initiator tRNAs have a unique anticodon loop conformation.

Transfer RNA (tRNA) molecules have been labeled with 32P at the 5' end and subjected to S1 nuclease digestion. The products were analyzed by high-resolution gel electrophoresis. Three initiator tRNAs and six chain-elongating tRNAs were examined. S1 nuclease cleaved Escherichia coli tRNAfMet, yeast tRNAfMet, and mammalian tRNAfMet at the same two positions in the anticodon loop. In contrast, S1 nuclease cleaved the anticodon loop of E. coli tRNAmMet, yeast tRNAmMet, yeast tRNAPhe, Schizosaccharomyces pombe tRNAPhe, E. coli tRNA2Glu, and E. coli tRNATrp (su+) at four positions generally, except where a modified nucleotide in the wobble position inhibited the enzyme. The marked contrast between these cleavage patterns suggests a different conformation for the anticodon loops of these two classes of tRNA molecules. It is suggested that the specialized conformation in the anticodon loop of initiator tRNAs may be due to a special sequence of GC base pairs in the adjoining anticodon stem.     

Structural basis for functional mimicry of long-variable-arm tRNA by transfer-messenger RNA

tmRNA and small protein B (SmpB) are essential trans-translation system components. In the present study, we determined the crystal structure of SmpB in complex with the entire tRNA domain of the tmRNA from Thermus thermophilus. Overall, the ribonucleoprotein complex (tRNP) mimics a long-variable-arm tRNA (class II tRNA) in the canonical L-shaped tertiary structure. The tmRNA terminus corresponds to the acceptor and T arms, or the upper part, of tRNA. On the other hand, the SmpB protein simulates the lower part, the anticodon and D stems, of tRNA. Intriguingly, several amino acid residues collaborate with tmRNA bases to reproduce the canonical tRNA core layers. The linker helix of tmRNA had been considered to correspond to the anticodon stem, but the complex structure unambiguously shows that it corresponds to the tRNA variable arm. The tmRNA linker helix, as well as the long variable arm of class II tRNA, may occupy the gap between the large and small ribosomal subunits. This suggested how the tRNA domain is connected to the mRNA domain entering the mRNA channel. A loop of SmpB in the tRNP is likely to participate in the interaction with alanyl-tRNA synthetase, which may be the mechanism for the promotion of tmRNA alanylation by the SmpB protein. Therefore, the tRNP may simulate a tRNA, both structurally and functionally, with respect to aminoacylation and ribosome entry.     

Transfer RNA mischarging mediated by a mutant Escherichia coli glutaminyl-tRNA synthetase.

We have isolated mutations in the Escherichia coli glnS gene encoding glutaminyl-tRNA synthetase [GlnS; L-glutamine:tRNAGln ligase (AMP-forming), EC 6.1.1.18] that give rise to gene products with altered specificity for tRNA and are designated "mischarging" enzymes. These were produced by nitrosoguanine mutagenesis of the glnS gene carried on a transducing phage (lambda pglnS+). We then selected for mischarging of su+3 tRNATyr with glutamine by requiring suppression of a glutamine-requiring beta-galactosidase amber mutation (lacZ1000). Three independently isolated mutants (glnS7, glnS8, and glnS9) were characterized by genetic and biochemical means. The enzymes encoded by glnS7, glnS8, and glnS9 appear to be highly selective for su+3 tRNATyr, because in vivo mischarging of other amber suppressor tRNAs was not detected. The GlnS mutants described here retain their capacity to correctly aminoacylate tRNAGln. All three independently isolated mutant genes encode proteins with isoelectric points that differ from those of the wild-type enzyme but are identical to each other. This suggests that only a single site in the enzyme structure is altered to give the observed mischarging properties. In vitro aminoacylation reactions with purified GlnS7 protein show that this enzyme can also mischarge some tRNA species lacking the amber anticodon. This is an example of mischarging phenotype conferred by a mutation in an aminoacyl-tRNA synthetase gene; the results are discussed in the context of earlier genetic studies with mutant tRNAs.