Cytosine 73 is a discriminator nucleotide in vivo for histidyl-tRNA in Escherichia coli

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.

A genomically modified Escherichia coli strain carrying an orthogonal E. coli histidyl-tRNA synthetase•tRNAHis pair

BACKGROUND

Development of new aminoacyl-tRNA synthetase (aaRS)•tRNA pairs is central for incorporation of novel non-canonical amino acids (ncAAs) into proteins via genetic code expansion (GCE). The Escherichia coli and Caulobacter crescentus histidyl-tRNA synthetases (HisRS) evolved divergent mechanisms of tRNA^His recognition that prevent their cross-reactivity. Although the E. coli HisRS•tRNA^His pair is a good candidate for GCE, its use in C. crescentus is limited by the lack of established genetic selection methods and by the low transformation efficiency of C. crescentus.

METHODS

E. coli was genetically engineered to use a C. crescentus HisRS•tRNA^His pair. Super-folder green fluorescent protein (sfGFP) and chloramphenicol acetyltransferase (CAT) were used as reporters for read-through assays. A library of 313 ncAAs coupled with the sfGFP reporter system was employed to investigate the specificity of E. coli HisRS in vivo.

RESULTS

A genomically modified E. coli strain (named MEOV1) was created. MEVO1 requires an active C. crescentus HisRS•tRNA^His pair for growth, and displays a similar doubling time as the parental E. coli strain. sfGFP- and CAT-based assays showed that the E. coli HisRS•tRNA^His pair is orthogonal in MEOV1 cells. A mutation in the anticodon loop of E. coli tRNA^His_CUA elevated its suppression efficiency by 2-fold.

CONCLUSIONS

The C. crescentus HisRS•tRNA^His pair functionally complements an E. coli ΔhisS strain. The E. coli HisRS•tRNA^His is orthogonal in MEOV1 cells. E. coli tRNA^His_CUA is an efficient amber suppressor in MEOV1.

GENERAL SIGNIFICANCE

We developed a platform that allows protein engineering of E. coli HisRS that should facilitate GCE in E. coli. This article is part of a Special Issue entitled "Biochemistry of Synthetic Biology - Recent Developments" Guest Editor: Dr. Ilka Heinemann and Dr. Patrick O'Donoghue.

Identifying the ligated amino acid of archaeal tRNAs based on positions outside the anticodon

Proper recognition of tRNAs by their aminoacyl-tRNA synthetase is essential for translation accuracy. Following evidence that the enzymes can recognize the correct tRNA even when anticodon information is masked, we search for additional nucleotide positions within the tRNA molecule that potentially contain information for amino acid identification. Analyzing 3936 sequences of tRNA genes from 86 archaeal species, we show that the tRNAs' cognate amino acids can be identified by the information embedded in the tRNAs' nucleotide positions without relying on the anticodon information. We present a small set of six to 10 informative positions along the tRNA, which allow for amino acid identification accuracy of 90.6% to 97.4%, respectively. We inspected tRNAs for each of the 20 amino acid types for such informative positions and found that tRNA genes for some amino acids are distinguishable from others by as few as one or two positions. The informative nucleotide positions are in agreement with nucleotide positions that were experimentally shown to affect the loaded amino acid identity. Interestingly, the knowledge gained from the tRNA genes of one archaeal phylum does not extrapolate well to another phylum. Furthermore, each species has a unique ensemble of nucleotides in the informative tRNA positions, and the similarity between the sets of positions of two distinct species reflects their evolutionary distance. Hence, we term this set of informative positions a "tRNA cipher." It is tempting to suggest that the diverging code identified here might also serve the aminoacyl tRNA synthetase in the task of tRNA recognition.

Structural basis for recognition of G-1-containing tRNA by histidyl-tRNA synthetase

Aminoacyl-tRNA synthetases (aaRSs) play a crucial role in protein translation by linking tRNAs with cognate amino acids. Among all the tRNAs, only tRNA^His bears a guanine base at position -1 (G-1), and it serves as a major recognition element for histidyl-tRNA synthetase (HisRS). Despite strong interests in the histidylation mechanism, the tRNA recognition and aminoacylation details are not fully understood. We herein present the 2.55 Å crystal structure of HisRS complexed with tRNA^His, which reveals that G-1 recognition is principally nonspecific interactions on this base and is made possible by an enlarged binding pocket consisting of conserved glycines. The anticodon triplet makes additional specific contacts with the enzyme but the rest of the loop is flexible. Based on the crystallographic and biochemical studies, we inferred that the uniqueness of histidylation system originates from the enlarged binding pocket (for the extra base G-1) on HisRS absent in other aaRSs, and this structural complementarity between the 5′ extremity of tRNA and enzyme is probably a result of coevolution of both.

From end to end: tRNA editing at 5'- and 3'-terminal positions

During maturation, tRNA molecules undergo a series of individual processing steps, ranging from exo- and endonucleolytic trimming reactions at their 5'- and 3'-ends, specific base modifications and intron removal to the addition of the conserved 3'-terminal CCA sequence. Especially in mitochondria, this plethora of processing steps is completed by various editing events, where base identities at internal positions are changed and/or nucleotides at 5'- and 3'-ends are replaced or incorporated. In this review, we will focus predominantly on the latter reactions, where a growing number of cases indicate that these editing events represent a rather frequent and widespread phenomenon. While the mechanistic basis for 5'- and 3'-end editing differs dramatically, both reactions represent an absolute requirement for generating a functional tRNA. Current in vivo and in vitro model systems support a scenario in which these highly specific maturation reactions might have evolved out of ancient promiscuous RNA polymerization or quality control systems.

Identification of the determinants of tRNA function and susceptibility to rapid tRNA decay by high-throughput in vivo analysis

In order to comprehensively define the effects of sequence variation on tRNA function, Guy et al. developed a high-throughput in vivo screen to quantify the activity of the nonsense suppressor SUP4oc of Saccharomyces cerevisiae. SUP4oc tolerated numerous sequence variations, accommodated slippage in tertiary and secondary interactions, and exhibited genetic interactions that suggest an alternative functional tRNA conformation. Mutations that sensitized SUP4oc to rapid tRNA decay were found to be located throughout the sequence. This shows that the integrity of the entire tRNA molecule is under surveillance by cellular quality control machinery.

Sequence variation in tRNA genes influences the structure, modification, and stability of tRNA; affects translation fidelity; impacts the activity of numerous isodecoders in metazoans; and leads to human diseases. To comprehensively define the effects of sequence variation on tRNA function, we developed a high-throughput in vivo screen to quantify the activity of a model tRNA, the nonsense suppressor SUP4_oc of Saccharomyces cerevisiae. Using a highly sensitive fluorescent reporter gene with an ochre mutation, fluorescence-activated cell sorting of a library of SUP4_oc mutant yeast strains, and deep sequencing, we scored 25,491 variants. Unexpectedly, SUP4_oc tolerates numerous sequence variations, accommodates slippage in tertiary and secondary interactions, and exhibits genetic interactions that suggest an alternative functional tRNA conformation. Furthermore, we used this methodology to define tRNA variants subject to rapid tRNA decay (RTD). Even though RTD normally degrades tRNAs with exposed 5′ ends, mutations that sensitize SUP4_oc to RTD were found to be located throughout the sequence, including the anti-codon stem. Thus, the integrity of the entire tRNA molecule is under surveillance by cellular quality control machinery. This approach to assess activity at high throughput is widely applicable to many problems in tRNA biology.

A freshwater cyanophage whose genome indicates close relationships to photosynthetic marine cyanomyophages

Bacteriophage S-CRM01 has been isolated from a freshwater strain of Synechococcus and shown to be present in the upper Klamath River valley in northern California and Oregon. The genome of this lytic T4-like phage has a 178,563 bp circular genetic map with 297 predicted protein-coding genes and 33 tRNA genes that represent all 20-amino-acid specificities. Analyses based on gene sequence and gene content indicate a close phylogenetic relationship to the 'photosynthetic' marine cyanomyophages infecting Synechococcus and Prochlorococcus. Such relatedness suggests that freshwater and marine phages can draw on a common gene pool. The genome can be considered as being comprised of three regions. Region 1 is populated predominantly with structural genes, recognized as such by homology to other T4-like phages and by identification in a proteomic analysis of purified virions. Region 2 contains most of the genes with roles in replication, recombination, nucleotide metabolism and regulation of gene expression, as well as 5 of the 6 signature genes of the photosynthetic cyanomyophages (hli03, hsp20, mazG, phoH and psbA; cobS is present in Region 3). Much of Regions 1 and 2 are syntenic with marine cyanomyophage genomes, except that a segment encompassing Region 2 is inverted. Region 3 contains a high proportion (85%) of genes that are unique to S-CRM01, as well as most of the tRNA genes. Regions 1 and 2 contain many predicted late promoters, with a combination of CTAAATA and ATAAATA core sequences. Two predicted genes that are unusual in phage genomes are homologues of cellular spoT and nusG.

Change of tRNA identity leads to a divergent orthogonal histidyl-tRNA synthetase/tRNAHis pair

Mature tRNA^His has at its 5′-terminus an extra guanylate, designated as G⁻¹. This is the major recognition element for histidyl-tRNA synthetase (HisRS) to permit acylation of tRNA^His with histidine. However, it was reported that tRNA^His of a subgroup of α-proteobacteria, including Caulobacter crescentus, lacks the critical G⁻¹ residue. Here we show that recombinant C. crescentus HisRS allowed complete histidylation of a C. crescentus tRNA^His transcript (lacking G⁻¹). The addition of G⁻¹ did not improve aminoacylation by C. crescentus HisRS. However, mutations in the tRNA^His anticodon caused a drastic loss of in vitro histidylation, and mutations of bases A73 and U72 also reduced charging. Thus, the major recognition elements in C. crescentus tRNA^His are the anticodon, the discriminator base and U72, which are recognized by the divergent (based on sequence similarity) C. crescentus HisRS. Transplantation of these recognition elements into an Escherichia coli tRNA^His template, together with addition of base U20a, created a competent substrate for C. crescentus HisRS. These results illustrate how a conserved tRNA recognition pattern changed during evolution. The data also uncovered a divergent orthogonal HisRS/tRNA^His pair.

tRNA(His) guanylyltransferase (THG1), a unique 3'-5' nucleotidyl transferase, shares unexpected structural homology with canonical 5'-3' DNA polymerases

All known DNA and RNA polymerases catalyze the formation of phosphodiester bonds in a 5' to 3' direction, suggesting this property is a fundamental feature of maintaining and dispersing genetic information. The tRNA(His) guanylyltransferase (Thg1) is a member of a unique enzyme family whose members catalyze an unprecedented reaction in biology: 3'-5' addition of nucleotides to nucleic acid substrates. The 2.3-Å crystal structure of human THG1 (hTHG1) reported here shows that, despite the lack of sequence similarity, hTHG1 shares unexpected structural homology with canonical 5'-3' DNA polymerases and adenylyl/guanylyl cyclases, two enzyme families known to use a two-metal-ion mechanism for catalysis. The ability of the same structural architecture to catalyze both 5'-3' and 3'-5' reactions raises important questions concerning selection of the 5'-3' mechanism during the evolution of nucleotide polymerases.

Template-dependent 3'-5' nucleotide addition is a shared feature of tRNAHis guanylyltransferase enzymes from multiple domains of life

The presence of an additional 5' guanosine residue (G(-1)) is a unique feature of tRNA(His). G(-1) is incorporated posttranscriptionally in eukarya via an unusual 3'-5' nucleotide addition reaction catalyzed by the tRNA(His) guanylyltransferase (Thg1). Yeast Thg1 catalyzes an unexpected second activity: Watson-Crick-dependent 3'-5' nucleotide addition that occurs in the opposite direction to nucleotide addition by all known DNA and RNA polymerases. This discovery led to the hypothesis that there are alternative roles for Thg1 family members that take advantage of this unusual enzymatic activity. Here we show that archaeal homologs of Thg1 catalyze G(-1) addition, in vitro and in vivo in yeast, but only in a templated reaction, i.e. with tRNA(His) substrates that contain a C(73) discriminator nucleotide. Because tRNA(His) from archaea contains C(73), these findings are consistent with a physiological function for templated nucleotide addition in archaeal tRNA(His) maturation. Moreover, unlike yeast Thg1, archaeal Thg1 enzymes also exhibit a preference for template-dependent U(-1) addition to A(73)-containing tRNA(His). Taken together, these results demonstrate that Watson-Crick template-dependent 3'-5' nucleotide addition is a shared catalytic activity exhibited by Thg1 family members from multiple domains of life, and therefore, that this unusual reaction may constitute an ancestral activity present in the earliest members of the Thg1 enzyme family.

Intraphylum diversity and complex evolution of cyanobacterial aminoacyl-tRNA synthetases

A comparative genomic analysis of 35 cyanobacterial strains has revealed that the gene complement of aminoacyl-tRNA synthetases (AARSs) and routes for aminoacyl-tRNA synthesis may differ among the species of this phylum. Several genes encoding AARS paralogues were identified in some genomes. In-depth phylogenetic analysis was done for each of these proteins to gain insight into their evolutionary history. GluRS, HisRS, ArgRS, ThrRS, CysRS, and Glu-Q-RS showed evidence of a complex evolutionary course as indicated by a number of inconsistencies with our reference tree for cyanobacterial phylogeny. In addition to sequence data, support for evolutionary hypotheses involving horizontal gene transfer or gene duplication events was obtained from other observations including biased sequence conservation, the presence of indels (insertions or deletions), or vestigial traces of ancestral redundant genes. We present evidences for a novel protein domain with two putative transmembrane helices recruited independently by distinct AARS in particular cyanobacteria.

Kinetic discrimination of tRNA identity by the conserved motif 2 loop of a class II aminoacyl-tRNA synthetase

The selection of tRNAs by their cognate aminoacyl-tRNA synthetases is critical for ensuring the fidelity of protein synthesis. While nucleotides that comprise tRNA identity sets have been readily identified, their specific role in the elementary steps of aminoacylation is poorly understood. By use of a rapid kinetics analysis employing mutants in tRNA(His) and its cognate aminoacyl-tRNA synthetase, the role of tRNA identity in aminoacylation was investigated. While mutations in the tRNA anticodon preferentially affected the thermodynamics of initial complex formation, mutations in the acceptor stem or the conserved motif 2 loop of the tRNA synthetase imposed a specific kinetic block on aminoacyl transfer and decreased tRNA-mediated kinetic control of amino acid activation. The mechanistic basis of tRNA identity is analogous to fidelity control by DNA polymerases and the ribosome, whose reactions also demand high accuracy.

Loss of a universal tRNA feature

tRNA(His) has thus far always been found with one of the most distinctive of tRNA features, an extra 5' nucleotide that is usually a guanylate. tRNA(His) genes in a disjoint alphaproteobacterial group comprising the Rhizobiales, Rhodobacterales, Caulobacterales, Parvularculales, and Pelagibacter generally fail to encode this extra guanylate, unlike those of other alphaproteobacteria and bacteria in general. Rather than adding an extra 5' guanylate posttranscriptionally as eukaryotes do, evidence is presented here that two of these species, Sinorhizobium meliloti and Caulobacter crescentus, simply lack any extra nucleotide on tRNA(His). This loss correlates with changes at the 3' end sequence of tRNA(His) and at many sites in histidyl-tRNA synthetase that might be expected to affect tRNA(His) recognition, in the flipping loop, the insertion domain, the anticodon-binding domain, and the motif 2 loop. The altered tRNA charging system may have affected other tRNA charging systems in these bacteria; for example, a site in tRNA(Glu) sequences was found to covary with tRNA(His) among alphaproteobacteria.

Evolutionary conservation of a functionally important backbone phosphate group critical for aminoacylation of histidine tRNAs

All histidine tRNA molecules have an extra nucleotide, G-1, at the 5' end of the acceptor stem. In bacteria, archaea, and eukaryotic organelles, G-1 base pairs with C73, while in eukaryotic cytoplasmic tRNAHis, G-1 is opposite A73. Previous studies of Escherichia coli histidyl-tRNA synthetase (HisRS) have demonstrated the importance of the G-1:C73 base pair to tRNAHis identity. Specifically, the 5'-monophosphate of G-1 and the major groove amine of C73 are recognized by E. coli HisRS; these individual atomic groups each contribute approximately 4 kcal/mol to transition state stabilization. In this study, two chemically synthesized 24-nucleotide RNA microhelices, each of which recapitulates the acceptor stem of either E. coli or Saccharomyces cervisiae tRNAHis, were used to facilitate an atomic group "mutagenesis" study of the -1:73 base pair recognition by S. cerevisiae HisRS. Compared with E. coli HisRS, microhelixHis is a much poorer substrate relative to full-length tRNAHis for the yeast enzyme. However, the data presented here suggest that, similar to the E. coli system, the 5' monophosphate of yeast tRNA(His) is critical for aminoacylation by yeast HisRS and contributes approximately 3 kcal/mol to transition state stability. The primary role of the unique -1:73 base pair of yeast tRNAHis appears to be to properly position the critical 5' monophosphate for interaction with the yeast enzyme. Our data also suggest that the eukaryotic HisRS/tRNAHis interaction has coevolved to rely less on specific major groove interactions with base atomic groups than the bacterial system.

tRNAHis maturation: an essential yeast protein catalyzes addition of a guanine nucleotide to the 5' end of tRNAHis

All tRNAHis molecules are unusual in having an extra 5' GMP residue (G(-1)) that, in eukaryotes, is added after transcription and RNase P cleavage. Incorporation of this G(-1) residue is a rare example of nucleotide addition occurring at an RNA 5' end in a normal phosphodiester linkage. We show here that the essential Saccharomyces cerevisiae ORF YGR024c (THG1) is responsible for this guanylyltransferase reaction. Thg1p was identified by survey of a genomic collection of yeast GST-ORF fusion proteins for addition of [alpha-32P]GTP to tRNAHis. End analysis confirms the presence of G(-1). Thg1p is required for tRNAHis guanylylation in vivo, because cells depleted of Thg1p lack G(-1) in their tRNAHis. His6-Thg1p purified from Escherichia coli catalyzes the guanylyltransferase step of G(-1) addition using a ppp-tRNAHis substrate, and appears to catalyze the activation step using p-tRNAHis and ATP. Thg1p is highlye conserved in eukaryotes, where G(-1) addition is necessary, and is not found in eubacteria, where G(-1) is genome-encoded. Thus, Thg1p is the first member of a new family of enzymes that can catalyze phosphodiester bond formation at the 5' end of RNAs, formally in a 3'-5' direction. Surprisingly, despite its varied activities, Thg1p contains no recognizable catalytic or functional domains.

Specific tyrosylation of the bulky tRNA-like structure of brome mosaic virus RNA relies solely on identity nucleotides present in its amino acid-accepting domain

Residues specifying aminoacylation by yeast tyrosyl-tRNA synthetase (TyrRS) of the tRNA-like structure present at the 3'-end of brome mosaic virus (BMV) RNA were determined by the in vitro approach using phage T7 transcripts. They correspond to nucleotides equivalent to base-pair C1-G72 and discriminator base A73 in the amino acid-acceptor branch of the molecule. No functional equivalents of the tyrosine anticodon residues, shown to be weakly involved in tyrosine identity of canonical tRNA(Tyr), were found in the BMV tRNA-like structure. This indicates a behaviour of this large and intricate molecule reminiscent of that of a minihelix derived from an amino acid-acceptor branch. Furthermore, iodine footprinting experiments performed on a tyrosylable BMV RNA transcript of 196 nt complexed to yeast TyrRS indicate that the amino acid-acceptor branch of the viral RNA is protected against cleavages as well as a hairpin domain, which is possibly located perpendicularly to its accepting branch. This domain without the canonical anticodon loop or the tyrosine anticodon acts as an anchor for TyrRS interaction leading to a better efficiency of tyrosylation.

Histidyl-tRNA synthetase

Histidyl-tRNA synthetase (HisRS) is responsible for the synthesis of histidyl-transfer RNA, which is essential for the incorporation of histidine into proteins. This amino acid has uniquely moderate basic properties and is an important group in many catalytic functions of enzymes. A compilation of currently known primary structures of HisRS shows that the subunits of these homo-dimeric enzymes consist of 420-550 amino acid residues. This represents a relatively short chain length among aminoacyl-tRNA synthetases (aaRS), whose peptide chain sizes range from about 300 to 1100 amino acid residues. The crystal structures of HisRS from two organisms and their complexes with histidine, histidyl-adenylate and histidinol with ATP have been solved. HisRS from Escherichia coli and Thermus thermophilus are very similar dimeric enzymes consisting of three domains: the N-terminal catalytic domain containing the six-stranded antiparallel beta-sheet and the three motifs characteristic of class II aaRS, a HisRS-specific helical domain inserted between motifs 2 and 3 that may contact the acceptor stem of the tRNA, and a C-terminal alpha/beta domain that may be involved in the recognition of the anticodon stem and loop of tRNA(His). The aminoacylation reaction follows the standard two-step mechanism. HisRS also belongs to the group of aaRS that can rapidly synthesize diadenosine tetraphosphate, a compound that is suspected to be involved in several regulatory mechanisms of cell metabolism. Many analogs of histidine have been tested for their properties as substrates or inhibitors of HisRS, leading to the elucidation of structure-activity relationships concerning configuration, importance of the carboxy and amino group, and the nature of the side chain. HisRS has been found to act as a particularly important antigen in autoimmune diseases such as rheumatic arthritis or myositis. Successful attempts have been made to identify epitopes responsible for the complexation with such auto-antibodies.

Amino acid acceptor identity switch of Escherichia coli tmRNA from alanine to histidine in vitro

According to a trans -translation model, tmRNA facilitates the resumption of translation that has been stalled on the ribosome with the 3' end of a terminator-less mRNA, to produce a chimera polypeptide of the nascent peptide and the tmRNA-encoding 11 amino acid-tag. The first alanine residue of the tag-sequence is encoded neither by mRNA nor by tmRNA. This alanine is a key molecule for this model, in which it is derived from the alanine moiety aminoacylated to tmRNA. This is supported only by the observation that a point mutation at the third base-pair position of the acceptor stem of Escherichia coli tmRNA that deprives it of its aminoacylation ability causes abolishment of tag-peptide synthesis in vitro. Here, we made an E. coli tmRNA mutant with a completely switched amino acid acceptor identity from alanine to histidine by transplanting the upper half of the acceptor stem of tRNAHis. This histidine acceptor tmRNA mutant still retained an ability of tag-specific amino acid incorporation into the polypeptide in an in vitro poly(U)-dependent tag-peptide synthesis system, with an altered amino acid composition. Histidine, which is not a constituent of the original tag-peptide, was incorporated into the mutant-directed tag. The molar ratio of amino acids incorporated is consistent with that in the tag-sequence with the only expected change being the first amino acid from alanine to histidine. These results indicate that the first alanine residue of the tag-peptide is actually derived from that aminoacylated to tmRNA and is substitutable by other amino acids during the trans -translation processes.

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.

Missense translation errors in Saccharomyces cerevisiae

We describe the development of a novel plasmid-based assay for measuring the in vivo frequency of misincorporation of amino acids into polypeptide chains in the yeast Saccharomyces cerevisiae. The assay is based upon the measurement of the catalytic activity of an active site mutant of type III chloramphenicol acetyl transferase (CATIII) expressed in S. cerevisiae. A His195(CAC)-->Tyr195(UAC) mutant of CATIII is completely inactive, but catalytic activity can be restored by misincorporation of histidine at the mutant UAC codon. The average error frequency of misincorporation of histidine at this tyrosine UAC codon in wild-type yeast strains was measured as 0. 5x10(-5) and this frequency was increased some 50-fold by growth in the presence of paromomycin, a known translational-error-inducing antibiotic. A detectable frequency of misincorporation of histidine at a mutant Ala195 GCU codon was also measured as 2x10(-5), but in contrast to the Tyr195-->His195 misincorporation event, the frequency of histidine misincorporation at Ala195 GCU was not increased by paromomycin, inferring that this error did not result from miscognate codon-anticodon interaction. The His195 to Tyr195 missense error assay was used to demonstrate increased frequencies of missense error at codon 195 in SUP44 and SUP46 mutants. These two mutants have previously been shown to exhibit a translation termination error phenotype and the sup44+ and sup46+ genes encode the yeast ribosomal proteins S4 and S9, respectively. These data represent the first accurate in vivo measurement of a specific mistranslation event in a eukaryotic cell and directly confirm that the eukaryotic ribosome plays an important role in controlling missense errors arising from non-cognate codon-anticodon interactions.

Catalytic defects in mutants of class II histidyl-tRNA synthetase from Salmonella typhimurium previously linked to decreased control of histidine biosynthesis regulation

The expression of histidine biosynthetic genes in enteric bacteria is regulated by an attenuation mechanism in which the level of histidyl-tRNA serves as a key sensor of the intracellular histidine pool. Among the early observations that led to the formation of this model for Salmonella typhimurium were the identification of mutants in the gene (hisS) encoding histidyl-tRNA synthetase. We report here the detailed biochemical characterization of five of these S. typhimurium bradytrophic mutants isolated by selection for resistance to histidine analogs, including identification of the deduced amino acid substitutions and determination of the resulting effects on the kinetics of adenylation and aminoacylation. Using the crystal structure of the closely related Escherichia coli histidyl-tRNA synthetase (HisRS) as a guide, two mutants were mapped to a highly conserved proline residue in motif 2 (P117S, P117Q), and were correlated with a fivefold decrease in the kcat for the pyrophosphate exchange reaction, as well as a tenfold increase in the Km for tRNA in the aminoacylation reaction. Another mutant substitution (A302T) mapped to a residue adjacent to the histidine binding pocket, leading to a tenfold increase in Km for histidine in the pyrophosphate exchange reaction. The remaining two mutants (S167F, N254T) substitute residues in or directly adjacent to the hinge region, which joins the insertion domain between motif 2 and motif 3 to the catalytic core, and cause the Km for tRNA to increase four- to tenfold. The kinetic analysis of these mutants establishes a direct link between critical interactions within the active site of HisRS and regulation of histidine biosynthesis, and provides further evidence for the importance of local conformational changes during the catalytic cycle.

tRNA(Pro) anticodon recognition by Thermus thermophilus prolyl-tRNA synthetase

BACKGROUND

Most aminoacyl-tRNA synthetases (aaRSs) specifically recognize all or part of the anticodon triplet of nucleotides of their cognate tRNAs. Class IIa and class IIb aaRSs possess structurally distinct tRNA anticodon-binding domains. The class IIb enzymes (LysRS, AspRS and AsnRS) have an N-terminal beta-barrel domain (OB-fold); the interactions of this domain with the anticodon stem-loop are structurally well characterised for AspRS and LysRS. Four out of five class IIa enzymes (ProRS, ThrRS, HisRS and GlyRS, but not SerRS) have a C-terminal anticodon-binding domain with an alpha/beta fold, not yet found in any other protein. The mode of RNA binding by this domain is hitherto unknown as is the rationale, if any, behind classification of anticodon-binding domains for different aaRSs.

RESULTS

The crystal structure of Thermus thermophilus prolyl-tRNA synthetase (ProRSTT) in complex with tRNA(Pro) has been determined at 3.5 A resolution by molecular replacement using the native enzyme structure. One tRNA molecule, of which only the lower two-thirds is well ordered, is found bound to the synthetase dimer. The C-terminal anticodon-binding domain binds to the anticodon stem-loop from the major groove side. Binding to tRNA by ProRSTT is reminiscent of the interaction of class IIb enzymes with cognate tRNAs, but only three of the anticodon-loop bases become splayed out (bases 35-37) rather than five (bases 33-37) in the case of class IIb enzymes. The two anticodon bases conserved in all tRNA(Pro), G35 and G36, are specifically recognised by ProRSTT.

CONCLUSIONS

For the synthetases possessing the class IIa anticodon-binding domain (ProRS, ThrRS and GlyRS, with the exception of HisRS), the two anticodon bases 35 and 36 are sufficient to uniquely identify the cognate tRNA (GG for proline, GU for threonine, CC for glycine), because these amino acids occupy full codon groups. The structure of ProRSTT in complex with its cognate tRNA shows that these two bases specifically interact with the enzyme, whereas base 34, which can be any base, is stacked under base 33 and makes no interactions with the synthetase. This is in agreement with biochemical experiments which identify bases 35 and 36 as major tRNA identity elements. In contrast, class IIb synthetases (AspRS, AsnRS and LysRS) have a distinct anticodon-binding domain that specifically recognises all three anticodon bases. This again correlates with the requirements of the genetic code for cognate tRNA identification, as the class IIb amino acids occupy half codon groups.

Human lysyl-tRNA synthetase accepts nucleotide 73 variants and rescues Escherichia coli double-defective mutant

The nucleotide 73 (N73) "discriminator" base in the acceptor stem is a key element for efficient and specific aminoacylation of tRNAs and of microhelix substrates derived from tRNA acceptor stems. This nucleotide was possibly one of the first to be used for differentiating among groups of early RNA substrates by tRNA synthetases. In contrast to many other synthetases, we report here that the class II human lysyl-tRNA synthetase is relatively insensitive to the nature of N73. We cloned, sequenced, and expressed the enzyme, which is a close homologue of the class II yeast aspartyl-tRNA synthetase whose co-crystal structure (with tRNAAsp) is known. The latter enzyme has a strong requirement for G73, which interacts with 4 of the 14 residues within the "motif 2" loop of the enzyme. Even though eukaryotic lysine tRNAs also encode G73, the motif 2 loop sequence of lysyl-tRNA synthetase differs at multiple positions from that of the aspartate enzyme. Indeed, the recombinant human lysine enzyme shows little preference for G, and even charges human tRNA transcripts encoding the A73 found in E. coli lysine tRNAs. Moreover, while the lysine enzyme is the only one in E. coli to be encoded by two separate genes, a double mutant that disables both genes is complemented by a cDNA expressing the human protein. Thus, the sequence of the loop of motif 2 of human lysyl-tRNA synthetase specifies a structural variation that accommodates nucleotide degeneracy at position 73. This sequence might be used as a starting point for obtaining highly specific interactions with any given N73 by simple amino acid replacements.

Strategy for RNA recognition by yeast histidyl-tRNA synthetase

Histidine aminoacylation systems are of interest because of the structural diversity of the RNA substrates recognized by histidyl-tRNA synthetases. Among tRNAs participating in protein synthesis, those specific for histidine all share an additional residue at their 5'-extremities. On the other hand, tRNA-like domains at the 3'--termini of some plant viruses can also be charged by histidyl-tRNA synthetases, although they are not actors in protein synthesis. This is the case for the RNAs from tobacco mosaic virus and its satellite virus but also those of turnip yellow and brome mosaic viruses. All these RNAs have intricate foldings at their 3'-termini differing from that of canonical tRNAs and share a pseudoknotted domain which is the prerequisite for their folding into structures mimicking the overall L-shape of tRNAs. This paper gives an overview on tRNA identity and rationalizes the apparently contradictory structural and aminoacylation features of histidine-specific tRNAs and tRNA-like structures. The discussion mainly relies on histidylation data obtained with the yeast synthetase, but the conclusions are of a more universal nature. In canonical tRNA(His), the major histidine identity element is the 'minus' 1 residue, since its removal impairs histidylation and conversely its addition to a non-cognate tRNA(Asp) confers histidine identity to the transplanted molecule. Optimal expression of histidine identity depends on the chemical nature of the -1 residue and is further increased and/or modulated by the discriminator base N73 and by residues in the anticodon. In the viral tRNA-like domains, the major identity determinant -1 is mimicked by a residue from the single-stranded L1 regions of the different pseudoknots. The consequences of this mimicry for the function of minimalist RNAs derived from tRNA-like domains are discussed. The characteristics of the histidine systems illustrate well the view that the core of the amino acid accepting RNAs is a scaffold that allows proper presentation of identity nucleotides to their amino acid identity counterparts in the synthetase and that different types of scaffoldings are possible.

RNase P from bacteria. Substrate recognition and function of the protein subunit

RNase P recognizes many different precursor tRNAs as well as other substrates and cleaves all of them accurately at the expected position. RNase P recognizes the tRNA structure of the precursor tRNA by a set of interactions between the catalytic RNA subunit and the T- and acceptor-stems mainly, although residues in the 5'-leader sequence as well as the 3'-terminal CCA are important. These conclusions have been reached by several studies on mutant precursor tRNAs as well as cross-linking studies between RNase P RNA and precursor tRNAs. The protein subunit of RNase P seems also to affect the way that the substrate is recognized as well as the range of substrates that can be used by RNase P, although the protein does not seem to interact directly with the substrates. The interaction between the protein and RNA subunits of RNase P has been extensively studied in vitro. The protein subunit sequence is not highly conserved among bacteria, however different proteins are functionally equivalent as heterologous reconstitution of the RNase P holoenzyme can be achieved in many cases.

Crystallization of Thermus thermophilus histidyl-tRNA synthetase and its complex with tRNAHis

Histidyl-tRNA synthetase (HisRS) has been purified from the extreme thermophile Thermus thermophilus. The protein has been crystallized separately with histidine and with its cognate tRNAHis. Both crystals have been obtained using the vapor diffusion method with ammonium sulphate as precipitant. The crystals of HisRS with histidine belong to the spacegroup P2(1)2(1)2 with cell parameters a = 171.3 A, b = 214.7 A, c = 49.3 A, alpha = beta = gamma = 90 degrees. A complete data set to a resolution of 2.7A with an Rmerge on intensities of 4.1% has been collected on a single frozen crystal. A partial data set collected on a crystal of HisRS in complex with tRNAHis shows that the crystals are tetragonal with cell parameters a = b = 232 A, c = 559 A, alpha = beta = gamma = 90 degrees and diffract to about 4.5 A resolution.