Anticodon switching changes the identity of methionine and valine transfer RNAs

The tRNA identity landscape for aminoacylation and beyond

tRNAs are key partners in ribosome-dependent protein synthesis. This process is highly dependent on the fidelity of tRNA aminoacylation by aminoacyl-tRNA synthetases and relies primarily on sets of identities within tRNA molecules composed of determinants and antideterminants preventing mischarging by non-cognate synthetases. Such identity sets were discovered in the tRNAs of a few model organisms, and their properties were generalized as universal identity rules. Since then, the panel of identity elements governing the accuracy of tRNA aminoacylation has expanded considerably, but the increasing number of reported functional idiosyncrasies has led to some confusion. In parallel, the description of other processes involving tRNAs, often well beyond aminoacylation, has progressed considerably, greatly expanding their interactome and uncovering multiple novel identities on the same tRNA molecule. This review highlights key findings on the mechanistics and evolution of tRNA and tRNA-like identities. In addition, new methods and their results for searching sets of multiple identities on a single tRNA are discussed. Taken together, this knowledge shows that a comprehensive understanding of the functional role of individual and collective nucleotide identity sets in tRNA molecules is needed for medical, biotechnological and other applications.

Prebiotic Assembly of Cloverleaf tRNA, Its Aminoacylation and the Origin of Coding, Inferred from Acceptor Stem Coding-Triplets

tRNA is a key component in life's most fundamental process, the translation of the instructions contained in mRNA into proteins. Its role had to be executed as soon as the earliest translation emerged, but the questions of the prebiotic tRNA materialization, aminoacylation, and the origin of the coding triplets it carries are still open. Here, these questions are addressed by utilizing a distinct pattern of coding triplets highly conserved in the acceptor stems from the modern bacterial tRNAs of five early-emerging amino acids. Self-assembly of several copies of a short RNA oligonucleotide that carries a related pattern of coding triplets, via a simple and statistically feasible process, is suggested to result in a proto-tRNA model highly compatible with the cloverleaf secondary structure of the modern tRNA. Furthermore, these stem coding triplets evoke the possibility that they were involved in self-aminoacylation of proto-tRNAs prior to the emergence of the earliest synthetases, a process proposed to underlie the formation of the genetic code. Being capable of autonomous materialization and of self-aminoacylation, this verifiable model of the proto-tRNA advent adds principal components to an initial set of molecules and processes that may have led, exclusively through natural means, to the emergence of life.

Biochemistry of Aminoacyl tRNA Synthetase and tRNAs and Their Engineering for Cell-Free and Synthetic Cell Applications

Cell-free biology is increasingly utilized for engineering biological systems, incorporating novel functionality, and circumventing many of the complications associated with cells. The central dogma describes the information flow in biology consisting of transcription and translation steps to decode genetic information. Aminoacyl tRNA synthetases (AARSs) and tRNAs are key components involved in translation and thus protein synthesis. This review provides information on AARSs and tRNA biochemistry, their role in the translation process, summarizes progress in cell-free engineering of tRNAs and AARSs, and discusses prospects and challenges lying ahead in cell-free engineering.

Whole-Genome Transformation Promotes tRNA Anticodon Suppressor Mutations under Stress

tRNAs are encoded by a large gene family, usually with several isogenic tRNAs interacting with the same codon. Mutations in the anticodon region of other tRNAs can overcome specific tRNA deficiencies. Phylogenetic analysis suggests that such mutations have occurred in evolution, but the driving force is unclear. We show that in yeast suppressor mutations in other tRNAs are able to overcome deficiency of the essential TRT2-encoded tRNAThrCGU at high temperature (40°C). Surprisingly, these tRNA suppressor mutations were obtained after whole-genome transformation with DNA from thermotolerant Kluyveromyces marxianus or Ogataea polymorpha strains but from which the mutations did apparently not originate. We suggest that transient presence of donor DNA in the host facilitates proliferation at high temperature and thus increases the chances for occurrence of spontaneous mutations suppressing defective growth at high temperature. Whole-genome sequence analysis of three transformants revealed only four to five nonsynonymous mutations of which one causing TRT2 anticodon stem stabilization and two anticodon mutations in non-threonyl-tRNAs, tRNALysCUU and tRNAeMetCAU, were causative. Both anticodon mutations suppressed lethality of TRT2 deletion and apparently caused the respective tRNAs to become novel substrates for threonyl-tRNA synthetase. Liquid chromatography-tandem mass spectrometry (LC-MS/MS) data could not detect any significant mistranslation, and reverse transcription-quantitative PCR results contradicted induction of the unfolded protein response. We suggest that stress conditions have been a driving force in evolution for the selection of anticodon-switching mutations in tRNAs as revealed by phylogenetic analysis.IMPORTANCE In this work, we have identified for the first time the causative elements in a eukaryotic organism introduced by applying whole-genome transformation and responsible for the selectable trait of interest, i.e., high temperature tolerance. Surprisingly, the whole-genome transformants contained just a few single nucleotide polymorphisms (SNPs), which were unrelated to the sequence of the donor DNA. In each of three independent transformants, we have identified a SNP in a tRNA, either stabilizing the essential tRNAThrCGU at high temperature or switching the anticodon of tRNALysCUU or tRNAeMetCAU into CGU, which is apparently enough for in vivo recognition by threonyl-tRNA synthetase. LC-MS/MS analysis indeed indicated absence of significant mistranslation. Phylogenetic analysis showed that similar mutations have occurred throughout evolution and we suggest that stress conditions may have been a driving force for their selection. The low number of SNPs introduced by whole-genome transformation may favor its application for improvement of industrial yeast strains.

Coding triplets in the tRNA acceptor-TΨC arm and their role in present and past tRNA recognition

The mechanism and evolution of the recognition scheme between key components of the translation system, that is, tRNAs, synthetases, and elongation factors, are fundamental issues in understanding the translation of genetic information into proteins. Statistical analysis of bacterial tRNA sequences reveals that for six amino acids, a string of 10 nucleotides preceding the tRNA 3' end carries cognate coding triplets to nearly full extent. The triplets conserved in positions 63-67 are implicated in the recognition by the elongation factor EF-Tu, and those conserved in positions 68-72, in the identification of cognate tRNAs, and their derived minihelices by class IIa synthetases. These coding triplets are suggested to have primordial origin, being engaged in aminoacylation of prebiotic tRNAs and in the establishment of the canonical codon set.

Aminoacyl-tRNA Synthetases and tRNAs for an Expanded Genetic Code: What Makes them Orthogonal?

In the past two decades, tRNA molecules and their corresponding aminoacyl-tRNA synthetases (aaRS) have been extensively used in synthetic biology to genetically encode post-translationally modified and unnatural amino acids. In this review, we briefly examine one fundamental requirement for the successful application of tRNA/aaRS pairs for expanding the genetic code. This requirement is known as “orthogonality”—the ability of a tRNA and its corresponding aaRS to interact exclusively with each other and avoid cross-reactions with additional types of tRNAs and aaRSs in a given organism.

Temperature dependent mistranslation in a hyperthermophile adapts proteins to lower temperatures

All organisms universally encode, synthesize and utilize proteins that function optimally within a subset of growth conditions. While healthy cells are thought to maintain high translational fidelity within their natural habitats, natural environments can easily fluctuate outside the optimal functional range of genetically encoded proteins. The hyperthermophilic archaeon Aeropyrum pernix (A. pernix) can grow throughout temperature variations ranging from 70 to 100°C, although the specific factors facilitating such adaptability are unknown. Here, we show that A. pernix undergoes constitutive leucine to methionine mistranslation at low growth temperatures. Low-temperature mistranslation is facilitated by the misacylation of tRNA^Leu with methionine by the methionyl-tRNA synthetase (MetRS). At low growth temperatures, the A. pernix MetRS undergoes a temperature dependent shift in tRNA charging fidelity, allowing the enzyme to conditionally charge tRNA^Leu with methionine. We demonstrate enhanced low-temperature activity for A. pernix citrate synthase that is synthesized during leucine to methionine mistranslation at low-temperature growth compared to its high-fidelity counterpart synthesized at high-temperature. Our results show that conditional leucine to methionine mistranslation can make protein adjustments capable of improving the low-temperature activity of hyperthermophilic proteins, likely by facilitating the increasing flexibility required for greater protein function at lower physiological temperatures.

Transfer RNA Modification

Transfer RNA (tRNA) from all organisms on this planet contains modified nucleosides, which are derivatives of the four major nucleosides. tRNA from Escherichia coli/Salmonella enterica contains 31 different modified nucleosides, which are all, except for one (Queuosine[Q]), synthesized on an oligonucleotide precursor, which through specific enzymes later matures into tRNA. The corresponding structural genes for these enzymes are found in mono- and polycistronic operons, the latter of which have a complex transcription and translation pattern. The syntheses of some of them (e.g.,several methylated derivatives) are catalyzed by one enzyme, which is position and base specific, but synthesis of some have a very complex biosynthetic pathway involving several enzymes (e.g., 2-thiouridines, N6-threonyladenosine [t6A],and Q). Several of the modified nucleosides are essential for viability (e.g.,lysidin, t6A, 1-methylguanosine), whereas deficiency in others induces severe growth defects. However, some have no or only a small effect on growth at laboratory conditions. Modified nucleosides that are present in the anticodon loop or stem have a fundamental influence on the efficiency of charging the tRNA, reading cognate codons, and preventing missense and frameshift errors. Those, which are present in the body of the tRNA, have a primarily stabilizing effect on the tRNA. Thus, the ubiquitouspresence of these modified nucleosides plays a pivotal role in the function of the tRNA by their influence on the stability and activity of the tRNA.

Transfer RNA Modification: Presence, Synthesis, and Function

Transfer RNA (tRNA) from all organisms on this planet contains modified nucleosides, which are derivatives of the four major nucleosides. tRNA from Escherichia coli/Salmonella enterica serovar Typhimurium contains 33 different modified nucleosides, which are all, except one (Queuosine [Q]), synthesized on an oligonucleotide precursor, which by specific enzymes later matures into tRNA. The structural genes for these enzymes are found in mono- and polycistronic operons, the latter of which have a complex transcription and translation pattern. The synthesis of the tRNA-modifying enzymes is not regulated similarly, and it is not coordinated to that of their substrate, the tRNA. The synthesis of some of them (e.g., several methylated derivatives) is catalyzed by one enzyme, which is position and base specific, whereas synthesis of some has a very complex biosynthetic pathway involving several enzymes (e.g., 2-thiouridines, N  6-cyclicthreonyladenosine [ct6A], and Q). Several of the modified nucleosides are essential for viability (e.g., lysidin, ct6A, 1-methylguanosine), whereas the deficiency of others induces severe growth defects. However, some have no or only a small effect on growth at laboratory conditions. Modified nucleosides that are present in the anticodon loop or stem have a fundamental influence on the efficiency of charging the tRNA, reading cognate codons, and preventing missense and frameshift errors. Those that are present in the body of the tRNA primarily have a stabilizing effect on the tRNA. Thus, the ubiquitous presence of these modified nucleosides plays a pivotal role in the function of the tRNA by their influence on the stability and activity of the tRNA.

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 tRNACAU(Met) from near-cognate tRNACAU(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.

Convergent evolution of two different random RNAs for specific interaction with methionyl-tRNA synthetase

Aminoacyl-tRNA synthetases (ARSs) recognize a specific sequence or structural characteristics of their cognate tRNAs. To contribute to the understanding how these recognition sites were selected, we generated two different RNA libraries containing either 42mer or 70mer random sequence and used them to select RNA aptamers that specifically bound to methionyl-tRNA synthetase (MRS) of Mycobacterium tuberculosis. The aptamer pools selected from the two RNA libraries showed strong binding affinity and selectivity to M. tuberculosis MRS compared to that of the homologous Escherichia coli MRS. The RNA aptamers selected from the two completely unrelated RNA pools shared the octamer sequence including CAU and the anticodon sequence of tRNA(Met). The secondary structure prediction suggested that the octamer motif in the selected aptamers would form a loop similar to the anticodon loop of tRNA(Met). The results suggest that the RNA loop containing CAU triplet could selected as a major recognition site for MRS during evolution more or less regarding, and also showed that species-specific ARS inhibitors can be obtained by in vitro evolution.

Translation Initiation

Selection of correct start codons on messenger RNAs is a key step required for faithful translation of the genetic message. Such a selection occurs in a complex process, during which a translation-competent ribosome assembles, eventually having in its P site a specialized methionyl-tRNAMet base-paired with the start codon on the mRNA. This chapter summarizes recent advances describing at the molecular level the successive steps involved in the process. Special emphasis is put on the roles of the three initiation factors and of the initiator tRNA, which are crucial for the efficiency and the specificity of the process. In particular, structural analyses concerning complexes containing ribosomal subunits, as well as detailed kinetic studies, have shed new light on the sequence of events leading to faithful initiation of protein synthesis in Bacteria.

Misacylation of specific nonmethionyl tRNAs by a bacterial methionyl-tRNA synthetase

Aminoacyl-tRNA synthetases perform a critical step in translation by aminoacylating tRNAs with their cognate amino acids. Although high fidelity of aminoacyl-tRNA synthetases is often thought to be essential for cell biology, recent studies indicate that cells tolerate and may even benefit from tRNA misacylation under certain conditions. For example, mammalian cells selectively induce mismethionylation of nonmethionyl tRNAs, and this type of misacylation contributes to a cell's response to oxidative stress. However, the enzyme responsible for tRNA mismethionylation and the mechanism by which specific tRNAs are mismethionylated have not been elucidated. Here we show by tRNA microarrays and filter retention that the methionyl-tRNA synthetase enzyme from Escherichia coli (EcMRS) is sufficient to mismethionylate two tRNA species, and , indicating that tRNA mismethionylation is also present in the bacterial domain of life. We demonstrate that the anticodon nucleotides of these misacylated tRNAs play a critical role in conferring mismethionylation identity. We also show that a certain low level of mismethionylation is maintained for these tRNAs, suggesting that mismethionylation levels may have evolved to confer benefits to the cell while still preserving sufficient translational fidelity to ensure cell viability. EcMRS mutants show distinct effects on mismethionylation, indicating that many regions in this synthetase enzyme influence mismethionylation. Our results show that tRNA mismethionylation can be carried out by a single protein enzyme, mismethionylation also requires identity elements in the tRNA, and EcMRS has a defined structure-function relationship for tRNA mismethionylation.

Role for a conserved structural motif in assembly of a class I aminoacyl-tRNA synthetase active site

The catalytic domains of class I aminoacyl-tRNA synthetases are built around a conserved Rossmann nucleotide binding fold, with additional polypeptide domains responsible for tRNA binding or hydrolytic editing of misacylated substrates. Structural comparisons identified a conserved motif bridging the catalytic and anticodon binding domains of class Ia and Ib enzymes. This stem contact fold (SCF) has been proposed to globally orient each enzyme's cognate tRNA by interacting with the inner corner of the L-shaped tRNA. Despite the structural similarity of the SCF among class Ia/Ib enzymes, the sequence conservation is low. We replaced amino acids of the MetRS SCF with portions of the structurally similar glutaminyl-tRNA synthetase (GlnRS) motif or with alanine residues. Chimeric variants retained significant tRNA methionylation activity, indicating that structural integrity of the helix-turn-strand-helix motif contributes more to tRNA aminoacylation than does amino acid identity. In contrast, chimeras were significantly reduced in methionyl adenylate synthesis, suggesting a role for the SCF in formation of a structured active site domain. A highly conserved aspartic acid within the MetRS SCF is proposed to make an electrostatic interaction with an active site lysine; these residues were replaced with alanines or conservative substitutions. Both methionyl adenylate formation and methionine transfer were impaired, and activity was not significantly recovered by making the compensatory double substitution.

Effect of a domain-spanning disulfide on aminoacyl-tRNA synthetase activity

Enzymes regulated by allostery undergo conformational rearrangement upon binding effector molecules. For modular proteins, a flexible interface may mediate reorientation of the protein domains and transmit binding events to activate catalysis at a distance. Aminoacyl-tRNA synthetases (aaRSs) that use tRNA anticodons as identity elements can be considered allosteric enzymes in which aminoacylation of the tRNA acceptor stem is enhanced upon anticodon binding. We reasoned that anticodon-triggered conformational change might be restricted upon introduction of a disulfide linkage near the core of an aaRS. Here we show that a double cysteine mutation engineered at the Escherichia coli MetRS domain interface spontaneously generates a disulfide linkage. This disulfide clamp has no effect on methionyl adenylate formation but reduces the level of tRNA(Met) aminoacylation approximately 2-fold. Activity is restored upon chemical reduction of the disulfide, demonstrating that E. coli MetRS requires a flexible interface domain for full catalytic efficiency.

Pathology-related mutation A7526G (A9G) helps in the understanding of the 3D structural core of human mitochondrial tRNA(Asp)

More than 130 mutations in human mitochondrial tRNA (mt-tRNA) genes have been correlated with a variety of neurodegenerative and neuromuscular disorders. Their molecular impacts are of mosaic type, affecting various stages of tRNA biogenesis, structure, and/or functions in mt-translation. Knowledge of mammalian mt-tRNA structures per se remains scarce however. Primary and secondary structures deviate from classical tRNAs, while rules for three-dimensional (3D) folding are almost unknown. Here, we take advantage of a myopathy-related mutation A7526G (A9G) in mt-tRNA(Asp) to investigate both the primary molecular impact underlying the pathology and the role of nucleotide 9 in the network of 3D tertiary interactions. Experimental evidence is presented for existence of a 9-12-23 triple in human mt-tRNA(Asp) with a strongly conserved interaction scheme in mammalian mt-tRNAs. Mutation A7526G disrupts the triple interaction and in turn reduces aspartylation efficiency.

A disease-causing point mutation in human mitochondrial tRNAMet rsults in tRNA misfolding leading to defects in translational initiation and elongation

The mitochondrial tRNA genes are hot spots for mutations that lead to human disease. A single point mutation (T4409C) in the gene for human mitochondrial tRNA(Met) (hmtRNA(Met)) has been found to cause mitochondrial myopathy. This mutation results in the replacement of U8 in hmtRNA(Met) with a C8. The hmtRNA(Met) serves both in translational initiation and elongation in human mitochondria making this tRNA of particular interest in mitochondrial protein synthesis. Here we show that the single 8U-->C mutation leads to a failure of the tRNA to respond conformationally to Mg(2+). This mutation results in a drastic disruption of the structure of the hmtRNA(Met), which significantly reduces its aminoacylation. The small fraction of hmtRNA(Met) that can be aminoacylated is not formylated by the mitochondrial Met-tRNA transformylase preventing its function in initiation, and it is unable to form a stable ternary complex with elongation factor EF-Tu preventing any participation in chain elongation. We have used structural probing and molecular reconstitution experiments to examine the structures formed by the normal and mutated tRNAs. In the presence of Mg(2+), the normal tRNA displays the structural features expected of a tRNA. However, even in the presence of Mg(2+), the mutated tRNA does not form the cloverleaf structure typical of tRNAs. Thus, we believe that this mutation has disrupted a critical Mg(2+)-binding site on the tRNA required for formation of the biologically active structure. This work establishes a foundation for understanding the physiological consequences of the numerous mitochondrial tRNA mutations that result in disease in humans.

Role of tRNA-like structures in controlling plant virus replication

Transfer RNA-like structures (TLSs) that are sophisticated functional mimics of tRNAs are found at the 3'-termini of the genomes of a number of plant positive strand RNA viruses. Three natural aminoacylation identities are represented: valine, histidine, and tyrosine. Paralleling this variety in structure, the roles of TLSs vary widely between different viruses. For Turnip yellow mosaic virus, the TLS must be capable of valylation in order to support infectivity, major roles being the provision of translational enhancement and down-regulation of minus strand initiation. In contrast, valylation of the Peanut clump virus TLS is not essential. An intermediate situation seems to exist for Brome mosaic virus, whose RNAs 1 and 2, but not RNA 3, need to be capable of tyrosylation to support infectivity. Other known roles for certain TLSs include: (i) the recruitment of host CCA nucleotidyltransferase as a telomerase to maintain intact 3' CCA termini, (ii) involvement in the encapsidation of viral RNAs, and (iii) presentation of minus strand promoter elements for replicase recognition. In the latter role, the promoter elements reside within the TLS but are not functionally dependent on tRNA mimicry. The phylogenetic distribution of TLSs indicates that their evolutionary history includes frequent horizontal exchange, as has been observed for protein-coding regions of plant positive strand RNA viruses.

An operational RNA code for faithful assignment of AUG triplets to methionine

The assignment of AUG codons to methionine remains a central question of the evolution of the genetic code. We have unveiled a strategy for the discrimination among tRNAs containing CAU (AUG-decoding) anticodons. Mycoplasma penetrans methionyl-tRNA synthetase can directly differentiate between tRNA(Ile)(CAU) and tRNA(Met)(CAU) transcripts (a recognition normally achieved through the modification of anticodon bases). This discrimination mechanism is based only on interactions with the acceptor stems of tRNA(Ile)(CAU) and tRNA(Met)(CAU). Thus, in certain species, the fidelity of translation of methionine codons requires a discrimination mechanism that is independent of the information contained in the anticodon.

Virus-encoded aminoacyl-tRNA synthetases: structural and functional characterization of mimivirus TyrRS and MetRS

Aminoacyl-tRNA synthetases are pivotal in determining how the genetic code is translated in amino acids and in providing the substrate for protein synthesis. As such, they fulfill a key role in a process universally conserved in all cellular organisms from their most complex to their most reduced parasitic forms. In contrast, even complex viruses were not found to encode much translation machinery, with the exception of isolated components such as tRNAs. In this context, the discovery of four aminoacyl-tRNA synthetases encoded in the genome of mimivirus together with a full set of translation initiation, elongation, and termination factors appeared to blur what was once a clear frontier between the cellular and viral world. Functional studies of two mimivirus tRNA synthetases confirmed the MetRS specificity for methionine and the TyrRS specificity for tyrosine and conformity with the identity rules for tRNA(Tyr) for archea/eukarya. The atomic structure of the mimivirus tyrosyl-tRNA synthetase in complex with tyrosinol exhibits the typical fold and active-site organization of archaeal-type TyrRS. However, the viral enzyme presents a unique dimeric conformation and significant differences in its anticodon binding site. The present work suggests that mimivirus aminoacyl-tRNA synthetases function as regular translation enzymes in infected amoebas. Their phylogenetic classification does not suggest that they have been acquired recently by horizontal gene transfer from a cellular host but rather militates in favor of an intricate evolutionary relationship between large DNA viruses and ancestral eukaryotes.

Using molecular dynamics to map interaction networks in an aminoacyl-tRNA synthetase

Long-range functional communication is a hallmark of many enzymes that display allostery, or action-at-a-distance. Many aminoacyl-tRNA synthetases can be considered allosteric, in that their trinucleotide anticodons bind the enzyme at a site removed from their catalytic domains. Such is the case with E. coli methionyl-tRNA synthase (MetRS), which recognizes its cognate anticodon using a conserved tryptophan residue 50 A away from the site of tRNA aminoacylation. The lack of details regarding how MetRS and tRNA(Met) interact has limited efforts to deconvolute the long-range communication that occurs in this system. We have used molecular dynamics simulations to evaluate the mobility of wild-type MetRS and a Trp-461 variant shown previously by experiment to be deficient in tRNA aminoacylation. The simulations reveal that MetRS has significant mobility, particularly at structural motifs known to be involved in catalysis. Correlated motions are observed between residues in distant structural motifs, including the active site, zinc binding motif, and anticodon binding domain. Both mobility and correlated motions decrease significantly but not uniformly upon substitution at Trp-461. Mobility of some residues is essentially abolished upon removal of Trp-461, despite being tens of Angstroms away from the site of mutation and solvent exposed. This conserved residue does not simply participate in anticodon binding, as demonstrated experimentally, but appears to mediate the protein's distribution of structural ensembles. Finally, simulations of MetRS indicate that the ligand-free protein samples conformations similar to those observed in crystal structures with substrates and substrate analogs bound. Thus, there are low energetic barriers for MetRS to achieve the substrate-bound conformations previously determined by structural methods.

Specificity of Phage Display Selected Peptides for Modified Anticodon Stem and Loop Domains of tRNA

Protein recognition of RNA has been studied using Peptide Phage Display Libraries, but in the absence of RNA modifications. Peptides from two libraries, selected for binding the modified anticodon stem and loop (ASL) of human tRNA(LyS3) having 2-thiouridine (s(2)U34) and pseudouridine (psi39), bound the modified human ASL(Lys3)(s(2)U34;psi39) preferentially and had significant homology with RNA binding proteins. Selected peptides were narrowed to a manageable number using a less sensitive, but inexpensive assay before conducting intensive characterization. The affinity and specificity of the best binding peptide (with an N-terminal fluorescein) were characterized by fluorescence spectrophotometry. The peptide exhibited the highest binding affinity for ASL(LYS3)(s(2)U34; psi39), followed by the hypermodified ASL(Lys3) (mcm(5)s(2) U34; ms(2)t(6)A37) and the unmodified ASL(Lys3), but bound poorly to singly modified ASL(Lys3) constructs (psi39, ms(2)t(6)A37, s(2)34), ASL(Lys1,2) (t(6)A37) and Escherichia coli ASL(Glu) (s(2)U34). Thus, RNA modifications are potentially important recognition elements for proteins and can be targets for selective recognition by peptides.

Protection-based assays to measure aminoacyl-tRNA binding to translation initiation factors

To decipher the mechanisms of translation initiation, the stability of the complexes between tRNA and initiation factors has to be evaluated in a routine manner. A convenient method to measure the parameters of binding of an aminoacyl-tRNA to an initiation factor results from the property that, when specifically complexed to a protein, the aminoacyl-tRNA often resists spontaneous deacylation. This chapter describes the preparation of suitable aminoacyl-tRNA ligands and their use in evaluating the stability of their complexes with various initiation factors, such as e/aIF2 and e/aIF5B. The advantages and the limitations of the method are discussed.

A base pair at the bottom of the anticodon stem is reciprocally preferred for discrimination of cognate tRNAs by Escherichia coli lysyl- and glutaminyl-tRNA synthetases

Although the yeast amber suppressor tRNA(Tyr) is a good candidate for a carrier of unnatural amino acids into proteins, slight misacylation with lysine was found to occur in an Escherichia coli protein synthesis system. Although it was possible to restrain the mislysylation by genetically engineering the anticodon stem region of the amber suppressor tRNA(Tyr), the mutant tRNA showing the lowest acceptance of lysine was found to accept a trace level of glutamine instead. Moreover, the glutamine-acceptance of various tRNA(Tyr) transcripts substituted at the anticodon stem region varied in reverse proportion to the lysine-acceptance, similar to a 'seesaw'. The introduction of a C31-G39 base pair at the site was most effective for decreasing the lysine-acceptance and increasing the glutamine-acceptance. When the same substitution was introduced into E.coli tRNA(Lys) transcripts, the lysine-accepting activity was decreased by 100-fold and faint acceptance of glutamine was observed. These results may support the idea that there are some structural element(s) in the anticodon stem of tRNA, which are not shared by aminoacyl-tRNA synthetases that have similar recognition sites in the anticodon, such as E.coli lysyl- and glutaminyl-tRNA synthetases.

Loss of a primordial identity element for a mammalian mitochondrial aminoacylation system

In mammalian mitochondria the translational machinery is of dual origin with tRNAs encoded by a simplified and rapidly evolving mitochondrial (mt) genome and aminoacyl-tRNA synthetases (aaRS) coded by the nuclear genome, and imported. Mt-tRNAs are atypical with biased sequences, size variations in loops and stems, and absence of residues forming classical tertiary interactions, whereas synthetases appear typical. This raises questions about identity elements in mt-tRNAs and adaptation of their cognate mt-aaRSs. We have explored here the human mt-aspartate system in which a prokaryotic-type AspRS, highly similar to the Escherichia coli enzyme, recognizes a bizarre tRNA(Asp). Analysis of human mt-tRNA(Asp) transcripts confirms the identity role of the GUC anticodon as in other aspartylation systems but reveals the non-involvement of position 73. This position is otherwise known as the site of a universally conserved major aspartate identity element, G73, also known as a primordial identity signal. In mt-tRNA(Asp), position 73 can be occupied by any of the four nucleotides without affecting aspartylation. Sequence alignments of various AspRSs allowed placing Gly-269 at a position occupied by Asp-220, the residue contacting G73 in the crystallographic structure of E. coli AspRS-tRNA(Asp) complex. Replacing this glycine by an aspartate renders human mt-AspRS more discriminative to G73. Restriction in the aspartylation identity set, driven by a rapid mutagenic rate of the mt-genome, suggests a reverse evolution of the mt-tRNA(Asp) identity elements in regard to its bacterial ancestor.

tRNAs and tRNA mimics as cornerstones of aminoacyl-tRNA synthetase regulations

Structural plasticity of transfer RNA (tRNA) molecules is essential for interactions with their biological partners in aminoacylation reactions and during ribosome-dependent protein synthesis. This holds true when tRNAs are recruited for other functions than translation. Here we review regulation pathways where tRNAs and tRNA mimics play a pivotal role. We further discuss the importance of the identity signals used in aminoacylation that are also required to specify regulatory mechanisms. Such mechanisms are diverse and intervene in transcription, splicing and translation. Altogether, the review highlights the many manners architectural features of tRNA were selected by evolution to control biological key processes.

Structural basis for anticodon recognition by methionyl-tRNA synthetase

In the 2.7-A resolution crystal structure of methionyl-tRNA synthetase (MetRS) in complex with tRNA(Met) and a methionyl-adenylate analog, the tRNA anticodon loop is distorted to form a triple-base stack comprising C34, A35 and A38. A tryptophan residue stacks on C34 to extend the triple-base stack. In addition, C34 forms Watson-Crick-type hydrogen bonds with Arg357. This structure resolves the longstanding question of how MetRS specifically recognizes tRNA(Met).

Model-based inference of gene expression dynamics from sequence information

A dynamic model of prokaryotic gene expression is developed that makes considerable use of gene sequence information. The main contribution arises from the fact that the combined gene expression model allows us to access the impact of altering a nucleotide sequence on the dynamics of gene expression rates mechanistically. The high level of detail of the mathematical model is considered as an important step towards bringing together the tremendous amount of biological in-depth knowledge that has been accumulated at the molecular level, using a systems level analysis (in the sense of a bottom-up, inductive approach). This enables to the model to provide highly detailed insights into the various steps of the protein expression process and it allows us to access possible targets for model-based design. Taken as a whole, the mathematical gene expression model presented in this study provides a comprehensive framework for a thorough analysis of sequence-related effects on the stages of mRNA synthesis, mRNA degradation and ribosomal translation, as well as their nonlinear interconnectedness. Therefore, it may be useful in the rational design of recombinant bacterial protein synthesis systems, the modulation of enzyme activities in pathway design, in vitro protein biosynthesis, and RNA-based vaccination.

Breaking the stereo barrier of amino acid attachment to tRNA by a single nucleotide

Aminoacyl-tRNA synthetases are responsible for attaching amino acid residues to the tRNA 3'-end. The two classes of synthetases approach tRNA as mirror images, with opposite but symmetrical stereochemistries that allow the class I enzymes to attach amino acid residues to the 2'-hydroxyl group of the terminal ribose, whereas, the class II enzymes attach amino acid residues to the 3'-hydroxyl group. However, we show here that the attachment of cysteine to tRNA(Cys) by the class I cysteinyl-tRNA synthetase (CysRS) is flexible; the enzyme is capable of using either the 2' or 3'-hydroxyl group as the attachment site. The molecular basis for this flexibility was investigated. Introduction of the nucleotide U73 of tRNA(Cys) into tRNA(Val) was found to confer the flexibility. While valylation of the wild-type tRNA(Val) by the class I ValRS was strictly dependent on the terminal 2'-hydroxyl group, that of the U73 mutant of tRNA(Val) occurred at either the 2' or 3'-hydroxyl group. Thus, the single nucleotide U73 of tRNA has the ability to break the stereo barrier of amino acid attachment to tRNA, by mobilizing the 2' and 3'-hydroxyl groups of A76 in flexible geometry with respect to the tRNA acceptor stem.

The T-domain of cytosolic tRNAVal, an essential determinant for mitochondrial import

Import of tRNAs into plant mitochondria appears to be highly specific. We recently showed that the anticodon and the D-domain sequences are essential determinants for tRNAVal import into tobacco cell mitochondria. To determine the minimal set of elements required to direct import of a cytosol-specific tRNA species, tobacco cells were transformed with an Arabidopsis thaliana intron-containing tRNAMet-e gene carrying the D-domain and the anticodon of a valine tRNA. Although well expressed and processed into tobacco cells, this mutated tRNA was shown to remain in the cytosol. Furthermore, a mutant tRNAVal carrying the T-domain of the tRNAMet-e, although still efficiently recognized by the valyl-tRNA synthetase, is not imported into mitochondria. Altogether these results suggest that mutations affecting the core of a tRNA molecule also alter its import ability into plant mitochondria.

Functional idiosyncrasies of tRNA isoacceptors in cognate and noncognate aminoacylation systems

The specificity of transfer RNA aminoacylation by cognate aminoacyl-tRNA synthetase is a crucial step for synthesis of functional proteins. It is established that the aminoacylation identity of a single tRNA or of a family of tRNA isoacceptors is linked to the presence of positive signals (determinants) allowing recognition by cognate synthetases and negative signals (antideterminants) leading to rejection by the noncognate ones. The completion of identity sets was generally tested by transplantation of the corresponding nucleotides into one or several host tRNAs which acquire as a consequence the new aminoacylation specificities. Such transplantation experiments were also useful to detect peculiar structural refinements required for optimal expression of a given aminoacylation identity set within a host tRNA. This study explores expression of the defined yeast aspartate identity set into different tRNA scaffolds of a same specificity, namely the four yeast tRNA(Arg) isoacceptors. The goal was to investigate whether expression of the new identity is similar due to the unique specificity of the host tRNAs or whether it is differently expressed due to their peculiar sequences and structural features. In vitro transcribed native tRNA(Arg) isoacceptors and variants bearing the aspartate identity elements were prepared and their aminoacylation properties established. The four wild-type isoacceptors are active in arginylation with catalytic efficiencies in a 20-fold range and are inactive in aspartylation. While transplanted tRNA(1)(Arg) and tRNA(4)(Arg) are converted into highly efficient substrates for yeast aspartyl-tRNA synthetase, transplanted tRNA(2)(Arg) and tRNA(3)(Arg) remain poorly aspartylated. Search for antideterminants in these two tRNAs reveals idiosyncratic features. Conversion of the single base-pair C6-G67 into G6-C67, the pair present in tRNA(Asp), allows full expression of the aspartate identity in the transplanted tRNA(2)(Arg), but not in tRNA(3)(Arg). It is concluded that the different isoacceptor tRNAs protect themselves from misaminoacylation by idiosyncratic pathways of antidetermination.

A yeast arginine specific tRNA is a remnant aspartate acceptor

High specificity in aminoacylation of transfer RNAs (tRNAs) with the help of their cognate aminoacyl-tRNA synthetases (aaRSs) is a guarantee for accurate genetic translation. Structural and mechanistic peculiarities between the different tRNA/aaRS couples, suggest that aminoacylation systems are unrelated. However, occurrence of tRNA mischarging by non-cognate aaRSs reflects the relationship between such systems. In Saccharomyces cerevisiae, functional links between arginylation and aspartylation systems have been reported. In particular, it was found that an in vitro transcribed tRNAAsp is a very efficient substrate for ArgRS. In this study, the relationship of arginine and aspartate systems is further explored, based on the discovery of a fourth isoacceptor in the yeast genome, tRNA4Arg. This tRNA has a sequence strikingly similar to that of tRNAAsp but distinct from those of the other three arginine isoacceptors. After transplantation of the full set of aspartate identity elements into the four arginine isoacceptors, tRNA4Arg gains the highest aspartylation efficiency. Moreover, it is possible to convert tRNA4Arg into an aspartate acceptor, as efficient as tRNAAsp, by only two point mutations, C38 and G73, despite the absence of the major anticodon aspartate identity elements. Thus, cryptic aspartate identity elements are embedded within tRNA4Arg. The latent aspartate acceptor capacity in a contemporary tRNAArg leads to the proposal of an evolutionary link between tRNA4Arg and tRNAAsp genes.

Single amino acid changes in AspRS reveal alternative routes for expanding its tRNA repertoire in vivo

Aminoacyl-tRNA synthetases (aaRSs) are enzymes that are highly specific for their tRNA substrates. Here, we describe the expansion of a class IIb aaRS-tRNA specificity by a genetic selection that involves the use of a modified tRNA displaying an amber anticodon and the argE(amber) and lacZ(amber) reporters. The study was performed on Escherichia coli aspartyl-tRNA synthetase (AspRS) and amber tRNA(Asp). Nine AspRS mutants able to charge the amber tRNA(Asp) and to suppress the reporter genes were selected from a randomly mutated library. All the mutants exhibited a new amber tRNA(Asp) specificity in addition to the initial native tRNA(Asp). Six mutations were found in the anticodon-binding site located in the N-terminal OB-fold. The strongest suppressor was a mutation of residue Glu-93 that contacts specifically the anticodon nucleotide 34 in the crystal structure. The other mutations in the OB-fold were found at close distance from the anticodon in the so-called loop L45 and strand S1. They concern residues that do not contact tRNA(Asp) in the native complex. In addition, this study shows that suppressors can carry mutations located far from the anticodon-binding site. One such mutation was found in the synthetase hinge-module where it increases the tRNA(Asp)-charging rate, and two other mutations were found in the prokaryotic-specific insertion domain and the catalytic core. These mutants seem to act by indirect effects on the tRNA acceptor stem binding and on the conformation of the active site of the enzyme. Altogether, these data suggest the existence of various ways for modifying the mechanism of tRNA discrimination.

Aminoacylation properties of pathology-related human mitochondrial tRNA(Lys) variants

In vitro transcription has proven to be a successful tool for preparation of functional RNAs, especially in the tRNA field, in which, despite the absence of post-transcriptional modifications, transcripts are correctly folded and functionally active. Human mitochondrial (mt) tRNA(Lys) deviates from this principle and folds into various inactive conformations, due to the absence of the post-transcriptional modification m(1)A9 which hinders base-pairing with U64 in the native tRNA. Unavailability of a functional transcript is a serious drawback for structure/function investigations as well as in deciphering the molecular mechanisms by which point mutations in the mt tRNA(Lys) gene cause severe human disorders. Here, we show that an engineered in vitro transcribed "pseudo-WT" tRNA(Lys) variant is efficiently recognized by lysyl-tRNA synthetase and can substitute for the WT tRNA as a valuable reference molecule. This has been exploited in a systematic analysis of the effects on aminoacylation of nine pathology-related mutations described so far. The sole mutation located in a loop of the tRNA secondary structure, A8344G, does not affect aminoacylation efficiency. Out of eight mutations located in helical domains converting canonical Watson-Crick pairs into G-U pairs or C.A mismatches, six have no effect on aminoacylation (A8296G, U8316C, G8342A, U8356C, U8362G, G8363A), and two lead to drastic decreases (5000- to 7000-fold) in lysylation efficiencies (G8313A and G8328A). This screening, allowing for analysis of the primary impact level of all mutations affecting one tRNA under comparable conditions, indicates distinct molecular origins for different disorders.

Functional Molecular Mapping of Archaeal Translation Initiation Factor 2

Eukaryotic and archaeal initiation factors 2 (e/aIF2) are heterotrimeric proteins (alphabetagamma) carrying methionylated initiator tRNA to the small subunit of the ribosome. The three-dimensional structure of aIF2gamma from the Archaea Pyrococcus abyssi was previously solved. This subunit forms the core of the heterotrimer. The alpha and beta subunits bind the gamma, but do not interact together. aIF2gamma shows a high resemblance with elongation factor EF1-A. In this study, we characterize the role of each subunit in the binding of the methionylated initiator tRNA. Studying various aminoacyl-tRNA ligands shows that the methionyl group is a major determinant for recognition by aIF2. aIF2gamma alone is able to specifically bind Met-tRNAiMet, although with a reduced affinity as compared with the intact trimer. Site-directed mutagenesis confirms a binding mode of the tRNA molecule similar to that observed with the elongation factor. Under our assay conditions, aIF2beta is not involved in the docking of the tRNA molecule. In contrast, aIF2alpha provides the heterotrimer its full tRNA binding affinity. Furthermore, the isolated C-domain of aIF2alpha is responsible for binding of the alpha subunit to gamma. This binding involves an idiosyncratic loop of domain 2 of aIF2gamma. Association of the C-domain of aIF2alpha to aIF2gamma is enough to retrieve the binding affinity of tRNA for aIF2. The N-terminal and central domains of aIF2alpha do not interfere with tRNA binding. However, the N-domain of aIF2alpha interacts with RNA unspecifically. Based on this property, a possible contribution of aIF2alpha to formation of a productive complex between aIF2 and the small ribosomal subunit is envisaged.

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.

Transfer RNA determinants for translational editing by Escherichia coli valyl-tRNA synthetase

Valyl-tRNA synthetase (ValRS) has difficulty differentiating valine from structurally similar non-cognate amino acids, most prominently threonine. To minimize errors in aminoacylation and translation the enzyme catalyzes a proofreading (editing) reaction that is dependent on the presence of cognate tRNA(Val). Editing occurs at a site functionally distinct from the aminoacylation site of ValRS and previous results have shown that the 3'-terminus of tRNA(Val) is recognized differently at the two sites. Here, we extend these studies by comparing the contribution of aminoacylation identity determinants to productive recognition of tRNA(Val) at the aminoacylation and editing sites, and by probing tRNA(Val) for editing determinants that are distinct from those required for aminoacylation. Mutational analysis of Escherichia coli tRNA(Val) and identity switch experiments with non-cognate tRNAs reveal a direct relationship between the ability of a tRNA to be aminoacylated and its ability to stimulate the editing activity of ValRS. This suggests that at least a majority of editing by the enzyme entails prior charging of tRNA and that misacylated tRNA is a transient intermediate in the editing reaction.

Modulation of tRNAAla identity by inorganic pyrophosphatase

A highly sensitive assay of tRNA aminoacylation was developed that directly measures the fraction of aminoacylated tRNA by following amino acid attachment to the 3'-(32)P-labeled tRNA. When applied to Escherichia coli alanyl-tRNA synthetase, the assay allowed accurate measurement of aminoacylation of the most deleterious mutants of tRNA(Ala). The effect of tRNA(Ala) identity mutations on both aminoacylation efficiency (k(cat)/K(M)) and steady-state level of aminoacyl-tRNA was evaluated in the absence and presence of inorganic pyrophosphatase and elongation factor Tu. Significant levels of aminoacylation were achieved for tRNA mutants even when the k(cat)/K(M) value is reduced by as much as several thousandfold. These results partially reconcile the discrepancy between in vivo and in vitro analysis of tRNA(Ala) identity.

The tRNA specificity of Thermus thermophilus EF-Tu

By introducing a GAC anticodon, 21 different Escherichia coli tRNAs were misacylated with either phenylalanine or valine and assayed for their affinity to Thermus thermophilus elongation factor Tu (EF-Tu)*GTP by using a ribonuclease protection assay. The presence of a common esterified amino acid permits the thermodynamic contribution of each tRNA body to the overall affinity to be evaluated. The E. coli elongator tRNAs exhibit a wide range of binding affinities that varied from -11.7 kcal/mol for Val-tRNA(Glu) to -8.1 kcal/mol for Val-tRNA(Tyr), clearly establishing EF-Tu*GTP as a sequence-specific RNA-binding protein. Because the ionic strength dependence of k(off) varied among tRNAs, some of the affinity differences are the results of a different number of phosphate contacts formed between tRNA and protein. Because EF-Tu is known to contact only the phosphodiester backbone of tRNA, the observed specificity must be a consequence of an indirect readout mechanism.

How methionyl-tRNA synthetase creates its amino acid recognition pocket upon L-methionine binding

Amino acid selection by aminoacyl-tRNA synthetases requires efficient mechanisms to avoid incorrect charging of the cognate tRNAs. A proofreading mechanism prevents Escherichia coli methionyl-tRNA synthetase (EcMet-RS) from activating in vivo L-homocysteine, a natural competitor of L-methionine recognised by the enzyme. The crystal structure of the complex between EcMet-RS and L-methionine solved at 1.8 A resolution exhibits some conspicuous differences with the recently published free enzyme structure. Thus, the methionine delta-sulphur atom replaces a water molecule H-bonded to Leu13N and Tyr260O(eta) in the free enzyme. Rearrangements of aromatic residues enable the protein to form a hydrophobic pocket around the ligand side-chain. The subsequent formation of an extended water molecule network contributes to relative displacements, up to 3 A, of several domains of the protein. The structure of this complex supports a plausible mechanism for the selection of L-methionine versus L-homocysteine and suggests the possibility of information transfer between the different functional domains of the enzyme.

Importance of the anticodon sequence in the aminoacylation of tRNAs by methionyl-tRNA synthetase and by valyl-tRNA synthetase in an Archaebacterium

The mode of recognition of tRNAs by aminoacyl-tRNA synthetases and translation factors is largely unknown in archaebacteria. To study this process, we have cloned the wild type initiator tRNA gene from the moderate halophilic archaebacterium Haloferax volcanii and mutants derived from it into a plasmid capable of expressing the tRNA in these cells. Analysis of tRNAs in vivo show that the initiator tRNA is aminoacylated but is not formylated in H. volcanii. This result provides direct support for the notion that protein synthesis in archaebacteria is initiated with methionine and not with formylmethionine. We have analyzed the effect of two different mutations (CAU-->CUA and CAU-->GAC) in the anticodon sequence of the initiator tRNA on its recognition by the aminoacyl-tRNA synthetases in vivo. The CAU-->CUA mutant was not aminoacylated to any significant extent in vivo, suggesting the importance of the anticodon in aminoacylation of tRNA by methionyl-tRNA synthetase. This mutant initiator tRNA can, however, be aminoacylated in vitro by the Escherichia coli glutaminyl-tRNA synthetase, suggesting that the lack of aminoacylation is due to the absence in H. volcanii of a synthetase, which recognizes the mutant tRNA. Archaebacteria lack glutaminyl-tRNA synthetase and utilize a two-step pathway involving glutamyl-tRNA synthetase and glutamine amidotransferase to generate glutaminyl-tRNA. The lack of aminoacylation of the mutant tRNA indicates that this mutant tRNA is not a substrate for the H. volcanii glutamyl-tRNA synthetase. The CAU-->GAC anticodon mutant is most likely aminoacylated with valine in vivo. Thus, the anticodon plays an important role in the recognition of tRNA by at least two of the halobacterial aminoacyl-tRNA synthetases.

Transfer RNA recognition by aminoacyl-tRNA synthetases

The aminoacyl-tRNA synthetases are an ancient group of enzymes that catalyze the covalent attachment of an amino acid to its cognate transfer RNA. The question of specificity, that is, how each synthetase selects the correct individual or isoacceptor set of tRNAs for each amino acid, has been referred to as the second genetic code. A wealth of structural, biochemical, and genetic data on this subject has accumulated over the past 40 years. Although there are now crystal structures of sixteen of the twenty synthetases from various species, there are only a few high resolution structures of synthetases complexed with cognate tRNAs. Here we review briefly the structural information available for synthetases, and focus on the structural features of tRNA that may be used for recognition. Finally, we explore in detail the insights into specific recognition gained from classical and atomic group mutagenesis experiments performed with tRNAs, tRNA fragments, and small RNAs mimicking portions of tRNAs.

The accuracy of codon recognition by polypeptide release factors

The precision with which individual termination codons in mRNA are recognized by protein release factors (RFs) has been measured and compared with the decoding of sense codons by tRNA. An Escherichia coli system for protein synthesis in vitro with purified components was used to study the accuracy of termination by RF1 and RF2 in the presence or absence of RF3. The efficiency of factor-dependent termination at all sense codons differing from any of the three stop codons by a single mutation was measured and compared with the efficiency of termination at the three stop codons. RF1 and RF2 discriminate against sense codons related to stop codons by between 3 and more than 6 orders of magnitude. This high level of accuracy is obtained without energy-driven error correction (proofreading), in contrast to codon-dependent aminoacyl-tRNA recognition by ribosomes. Two codons, UAU and UGG, stand out as hotspots for RF-dependent premature termination.

2.9 A crystal structure of ligand-free tryptophanyl-tRNA synthetase: domain movements fragment the adenine nucleotide binding site

The crystal structure of ligand-free tryptophanyl-tRNA synthetase (TrpRS) was solved at 2.9 A using a combination of molecular replacement and maximum-entropy map/phase improvement. The dimeric structure (R = 23.7, Rfree = 26.2) is asymmetric, unlike that of the TrpRS tryptophanyl-5'AMP complex (TAM; Doublié S, Bricogne G, Gilmore CJ, Carter CW Jr, 1995, Structure 3:17-31). In agreement with small-angle solution X-ray scattering experiments, unliganded TrpRS has a conformation in which both monomers open, leaving only the tryptophan-binding regions of their active sites intact. The amino terminal alphaA-helix, TIGN, and KMSKS signature sequences, and the distal helical domain rotate as a single rigid body away from the dinucleotide-binding fold domain, opening the AMP binding site, seen in the TAM complex, into two halves. Comparison of side-chain packing in ligand-free TrpRS and the TAM complex, using identification of nonpolar nuclei (Ilyin VA, 1994, Protein Eng 7:1189-1195), shows that significant repacking occurs between three relatively stable core regions, one of which acts as a bearing between the other two. These domain rearrangements provide a new structural paradigm that is consistent in detail with the "induced-fit" mechanism proposed for TyrRS by Fersht et al. (Fersht AR, Knill-Jones JW, Beduelle H, Winter G, 1988, Biochemistry 27:1581-1587). Coupling of ATP binding determinants associated with the two catalytic signature sequences to the helical domain containing the presumptive anticodon-binding site provides a mechanism to coordinate active-site chemistry with relocation of the major tRNA binding determinants.

Yeast aspartyl-tRNA synthetase residues interacting with tRNA(Asp) identity bases connectively contribute to tRNA(Asp) binding in the ground and transition-state complex and discriminate against non-cognate tRNAs

Crystallographic studies of the aspartyl-tRNA synthetase-tRNA(Asp)complex from yeast identified on the enzyme a number of residues potentially able to interact with tRNA(Asp). Alanine replacement of these residues (thought to disrupt the interactions) was used in the present study to evaluate their importance in tRNA(Asp)recognition and acylation. The results showed that contacts with the acceptor A of tRNA(Asp)by amino acid residues interacting through their side-chain occur only in the acylation transition state, whereas those located near the G73 discriminator base occur also during initial binding of tRNA(Asp). Interactions with the anticodon bases provide the largest free energy contribution to stability of the enzyme-tRNA complex in its ground state. These contacts also favour catalysis, by acting connectively with each other and with those of G73, as shown by multiple mutant analysis. This implies structural communication transmitting the anticodon recognition signal to the distally located acylation site. This signal might be conveyed via tRNA(Asp)as suggested by the observed conformational change of this molecule upon interaction with AspRS. From binding free energy values corresponding to the different AspRS-tRNA(Asp)interaction domains, it might be concluded that upon complex formation, the anticodon interacts first. Finally, acylation efficiencies of AspRS mutants in the presence of pure tRNA(Asp)and non-fractionated tRNAs indicate that residues involved in the binding of identity bases also discriminate against non-cognate tRNAs.

Universal rules and idiosyncratic features in tRNA identity

Correct expression of the genetic code at translation is directly correlated with tRNA identity. This survey describes the molecular signals in tRNAs that trigger specific aminoacylations. For most tRNAs, determinants are located at the two distal extremities: the anticodon loop and the amino acid accepting stem. In a few tRNAs, however, major identity signals are found in the core of the molecule. Identity elements have different strengths, often depend more on k cat effects than on K m effects and exhibit additive, cooperative or anti-cooperative interplay. Most determinants are in direct contact with cognate synthetases, and chemical groups on bases or ribose moieties that make functional interactions have been identified in several systems. Major determinants are conserved in evolution; however, the mechanisms by which they are expressed are species dependent. Recent studies show that alternate identity sets can be recognized by a single synthetase, and emphasize the importance of tRNA architecture and anti-determinants preventing false recognition. Identity rules apply to tRNA-like molecules and to minimalist tRNAs. Knowledge of these rules allows the manipulation of identity elements and engineering of tRNAs with switched, altered or multiple specificities.

Activation of microhelix charging by localized helix destabilization

We report that aminoacylation of minimal RNA helical substrates is enhanced by mismatched or unpaired nucleotides at the first position in the helix. Previously, we demonstrated that the class I methionyl-tRNA synthetase aminoacylates RNA microhelices based on the acceptor stem of initiator and elongator tRNAs with greatly reduced efficiency relative to full-length tRNA substrates. The cocrystal structure of the class I glutaminyl-tRNA synthetase with tRNAGln revealed an uncoupling of the first (1.72) base pair of tRNAGln, and tRNAMet was proposed by others to have a similar base-pair uncoupling when bound to methionyl-tRNA synthetase. Because the anticodon is important for efficient charging of methionine tRNA, we thought that 1.72 distortion is probably effected by the synthetase-anticodon interaction. Small RNA substrates (minihelices, microhelices, and duplexes) are devoid of the anticodon triplet and may, therefore, be inefficiently aminoacylated because of a lack of anticodon-triggered acceptor stem distortion. To test this hypothesis, we constructed microhelices that vary in their ability to form a 1.72 base pair. The results of kinetic assays show that microhelix aminoacylation is activated by destabilization of this terminal base pair. The largest effect is seen when one of the two nucleotides of the pair is completely deleted. Activation of aminoacylation is also seen with the analogous deletion in a minihelix substrate for the closely related isoleucine enzyme. Thus, for at least the methionine and isoleucine systems, a built-in helix destabilization compensates in part for the lack of presumptive anticodon-induced acceptor stem distortion.

L-arginine recognition by yeast arginyl-tRNA synthetase

The crystal structure of arginyl-tRNA synthetase (ArgRS) from Saccharomyces cerevisiae, a class I aminoacyl-tRNA synthetase (aaRS), with L-arginine bound to the active site has been solved at 2.75 A resolution and refined to a crystallographic R-factor of 19.7%. ArgRS is composed predominantly of alpha-helices and can be divided into five domains, including the class I-specific active site. The N-terminal domain shows striking similarity to some completely unrelated proteins and defines a module which should participate in specific tRNA recognition. The C-terminal domain, which is the putative anticodon-binding module, displays an all-alpha-helix fold highly similar to that of Escherichia coli methionyl-tRNA synthetase. While ArgRS requires tRNAArg for the first step of the aminoacylation reaction, the results show that its presence is not a prerequisite for L-arginine binding. All H-bond-forming capability of L-arginine is used by the protein for the specific recognition. The guanidinium group forms two salt bridge interactions with two acidic residues, and one H-bond with a tyrosine residue; these three residues are strictly conserved in all ArgRS sequences. This tyrosine is also conserved in other class I aaRS active sites but plays several functional roles. The ArgRS structure allows the definition of a new framework for sequence alignments and subclass definition in class I aaRSs.