The crystal structure of a Thermus thermophilus tRNA acceptor stem microhelix at 1.6 Å resolution

tRNAs are aminoacylated with the correct amino acid by the cognate aminoacyl-tRNA synthetase. The tRNA/synthetase systems can be divided into two classes: class I and class II. Within class I, the tRNA identity elements that enable the specificity consist of complex sequence and structure motifs, whereas in class II the identity elements are assured by few and simple determinants, which are mostly located in the tRNA acceptor stem.The tRNA^Gly/glycyl-tRNA-synthetase (GlyRS) system is a special case regarding evolutionary aspects. There exist two different types of GlyRS, namely an archaebacterial/human type and an eubacterial type, reflecting the evolutionary divergence within this system. We previously reported the crystal structures of an Escherichia coli and of a human tRNA^Gly acceptor stem microhelix. Here we present the crystal structure of a thermophilic tRNA^Gly aminoacyl stem from Thermus thermophilus at 1.6 Å resolution and provide insight into the RNA geometry and hydration.     

Superposition of a tRNASer acceptor stem microhelix into the seryl-tRNA synthetase complex

Aminoacyl-tRNA synthetases catalyze the formation of aminoacyl-tRNAs. Seryl-tRNA synthetase is a class II synthetase, which depends on rather few and simple identity elements in tRNA(Ser) to determine the amino acid specificity. tRNA(Ser) acceptor stem microhelices can be aminoacylated with serine, which makes this part of the tRNA a valuable tool for investigating the structural motifs in a tRNA(Ser)-seryl-tRNA synthetase complex. A 1.8A-resolution tRNA(Ser) acceptor stem crystal structure was superimposed to a 2.9A-resolution crystal structure of a tRNA(Ser)-seryl-tRNA synthetase complex for a visualization of the binding environment of the tRNA(Ser) microhelix.     

Acceptor stem and anticodon RNA hairpin helix interactions with glutamine tRNA synthetase

The class I glutamine (Gln) tRNA synthetase interacts with the anticodon and acceptor stem of glutamine tRNA. RNA hairpin helices were designed to probe acceptor stem and anticodon stem-loop contacts. A seven-base pair RNA microhelix derived from the acceptor stem of tRNA^Gln was aminoacylated by Gln tRNA synthetase. Variants of the glutamine acceptor stem microhelix implicated the discriminator base as a major identity element for glutaminylation of the RNA helix. A second RNA microhelix representing the anticodon stem-loop competitively inhibited tRNA^Gln charging. However, the anticodon stem-loop microhelix did not enhance aminoacylation of the acceptor stem microhelix. Thus, transduction of the anticodon identity signal may require covalent continuity of the tRNA chain to trigger efficient aminoacylation.     

The 1.2 Å crystal structure of an E. coli tRNA acceptor stem microhelix reveals two magnesium binding sites

tRNA identity elements assure the correct aminoacylation of tRNAs by the cognate aminoacyl-tRNA synthetases. tRNA^Ser belongs to the so-called class II system, in which the identity elements are rather simple and are mostly located in the acceptor stem region, in contrast to ‘class I’, where tRNA determinants are more complex and are located within different regions of the tRNA.The structure of an Escherichia coli tRNA^Ser acceptor stem microhelix was solved by high resolution X-ray structure analysis. The RNA crystallizes in the space group C2, with one molecule per asymmetric unit and with the cell constants a = 35.79, b = 39.13, c = 31.37 Å, and β = 111.1°. A defined hydration pattern of 97 water molecules surrounds the tRNA^Ser acceptor stem microhelix. Additionally, two magnesium binding sites were detected in the tRNA^Ser aminoacyl stem.     

The crystal structure of a Thermus thermophilus tRNA(Gly) acceptor stem microhelix at 1.6 Å resolution

tRNAs are aminoacylated with the correct amino acid by the cognate aminoacyl-tRNA synthetase. The tRNA/synthetase systems can be divided into two classes: class I and class II. Within class I, the tRNA identity elements that enable the specificity consist of complex sequence and structure motifs, whereas in class II the identity elements are assured by few and simple determinants, which are mostly located in the tRNA acceptor stem. The tRNA(Gly)/glycyl-tRNA-synthetase (GlyRS) system is a special case regarding evolutionary aspects. There exist two different types of GlyRS, namely an archaebacterial/human type and an eubacterial type, reflecting the evolutionary divergence within this system. We previously reported the crystal structures of an Escherichia coli and of a human tRNA(Gly) acceptor stem microhelix. Here we present the crystal structure of a thermophilic tRNA(Gly) aminoacyl stem from Thermus thermophilus at 1.6? resolution and provide insight into the RNA geometry and hydration.     

Superposition of two tRNA acceptor stem crystal structures: Comparison of structure, ligands and hydration

We solved the X-ray structures of two Escherichia coli tRNA^Ser acceptor stem microhelices. As both tRNAs are aminoacylated by the same seryl-tRNA-synthetase, we performed a comparative structure analysis of both duplexes to investigate the helical conformation, the hydration patterns and magnesium binding sites. It is well accepted, that the hydration of RNA plays an important role in RNA-protein interactions and that the extensive solvent content of the minor groove has a special function in RNA. The detailed comparison of both tRNA^Ser microhelices provides insights into the structural arrangement of the isoacceptor tRNA aminoacyl stems with respect to the surrounding water molecules and may eventually help us to understand their biological function at atomic resolution.     

Crystal structure of the human tRNA microhelix isoacceptor G9990 at 1.18 Å resolution

The tRNA^Gly/Glycyl-tRNA synthetase system belongs to the so called ‘class II’ in which tRNA identity elements consist of relative few and simple motifs, as compared to ‘class I’ where the tRNA determinants are more complicated and spread over different parts of the tRNA, mostly including the anticodon. The determinants from ‘class II’ although, are located in the aminoacyl stem and sometimes include the discriminator base. There exist predominant structure differences for the Glycyl-tRNA-synthetases and for the tRNA^Gly identity elements comparing eucaryotic/archaebacterial and eubacterial systems.We focus on comparative X-ray structure analysis of tRNA^Gly acceptor stem microhelices from different organisms. Here, we report the X-ray structure of the human tRNA^Gly microhelix isoacceptor G9990 at 1.18 Å resolution. Superposition experiments to another human tRNA^Gly microhelix and a detailed comparison of the RNA hydration patterns show a great number of water molecules with identical positions in both RNAs. This is the first structure comparison of hydration layers from two isoacceptor tRNA microhelices with a naturally occurring base pair exchange.     

Crystal structure of a human tRNA(Gly) microhelix at 1.2A resolution

The tRNA^Gly/glycyl-tRNA synthetase (GlyRS) system belongs to the so-called ‘class II aminoacyl-tRNA synthetase system’ in which tRNA identity elements are assured by rather few and simple determinants mostly located in the tRNA acceptor stem. Regarding evolutionary aspects, the tRNA^Gly/GlyRS system is a special case. There exist two different types of GlyRS, namely an archaebacterial/human type and a eubacterial type reflecting an evolutionary divergence within this system.Here we report the crystal structure of a human tRNA^Gly acceptor stem microhelix at 1.2 Å resolution. The local geometric parameters of the microhelix and the water network surrounding the RNA are presented. The structure complements the previously published Escherichia coli tRNA^Gly aminoacyl stem structure.     

Comparative X-ray structure analysis of human and Escherichia coli tRNA(Gly) acceptor stem microhelices

tRNA identity elements assure the correct aminoacylation of tRNAs by the aminoacyl-tRNA synthetases with the cognate amino acid. The tRNA^Gly/glycyl-tRNA sythetase system is member of the so-called ‘class II system’ in which the tRNA determinants consist of rather simple elements. These are mostly located in the tRNA acceptor stem and in the glycine case additionally the discriminator base at position 73 is required. Within the glycine-tRNA synthetases, the archaebacterial/human and the eubacterial sytems differ with respect to their protein structures and the required tRNA identity elements, suggesting a unique evolutionary divergence.In this study, we present a comparison between the crystal structures of the eubacterial Escherichia coli and the human tRNA^Gly acceptor stem microhelices and their surrounding hydration patterns.     

Crystal structure of the E. coli tRNA aminoacyl stem isoacceptor RR-1660 at 2.0 Å resolution

Due to the redundancy of the genetic code there exist six mRNA codons for arginine and several tRNA^Arg isoacceptors which translate these triplets to protein within the context of the mRNA. The tRNA identity elements assure the correct aminoacylation of the tRNA with the cognate amino acid by the aminoacyl-tRNA-synthetases. In tRNA^Arg, the identity elements consist of the anticodon, parts of the D-loop and the discriminator base. The minor groove of the acceptor stem interacts with the arginyl-tRNA-synthetase. We crystallized different Escherichia coli tRNA^Arg acceptor stem helices and solved the structure of the tRNA^Arg isoacceptor RR-1660 microhelix by X-ray structure analysis. The acceptor stem helix crystallizes in the space group P1 with the cell constants a = 26.28, b = 28.92, c = 29.00 Å, α = 105.74, β = 99.01, γ = 97.44° and two molecules per asymmetric unit. The RNA hydration pattern consists of 88 bound water molecules. Additionally, one glycerol molecule is bound within the interface of the two RNA molecules.     

Half molecules of serine-specific transfer ribonucleic acids from yeast

The preparation and analysis of half molecules from tRNA^Ser are described. Two pG-halves were isolated which differed only in the presence or absence of an acetyl group on the cytidylic acid residue at position 12. The CCA-half derived from tRNA₁^Ser was isolated pure, while the CCA-half derived from tRNA₂^Ser was isolated as a mixture with the CCA-half from tRNA₁^Ser from which the terminal CpCpA had been cleaved off.The acceptor activity of the combined complementary half molecules was 90% of the one of intact tRNA^Ser. The Michaelis constant and maximal velocity of amino-acylation were found to be identical for tRNA^Ser and the combined fragments.When half molecules were present at different ratios in aminoacylation studies it was found that one pG-half molecule can mediate the charging of several CCA-half molecules. There are indications that the CCA-half molecule alone can accept some serine. The CCA-half molecule alone can be aminoacylated to a rather high degree in the presence of an excess of tRNA_ox^Ser or tRNA^Ser-a and to a small degree in the presence of tRNA_ox^Ala (yeast) but not at all in the presence of tRNA_ox^Phe or tRNA_ox^Val (E. coli).Combinations of half molecules from tRNA^Ser with the opposite half molecules from tRNA^Phe could not be aminoacylated with Ser or Phe or 15 other amino acids although one of the combinations was well associated according to gel electrophoresis and differential melting curves.     

Divergence of selenocysteine tRNA recognition by archaeal and eukaryotic O-phosphoseryl-tRNASec kinase

Selenocysteine (Sec) biosynthesis in archaea and eukaryotes requires three steps: serylation of tRNA^Sec by seryl-tRNA synthetase (SerRS), phosphorylation of Ser-tRNA^Sec by O-phosphoseryl-tRNA^Sec kinase (PSTK), and conversion of O-phosphoseryl-tRNA^Sec (Sep-tRNA^Sec) by Sep-tRNA:Sec-tRNA synthase (SepSecS) to Sec-tRNA^Sec. Although SerRS recognizes both tRNA^Sec and tRNA^Ser species, PSTK must discriminate Ser-tRNA^Sec from Ser-tRNA^Ser. Based on a comparison of the sequences and secondary structures of archaeal tRNA^Sec and tRNA^Ser, we introduced mutations into Methanococcus maripaludis tRNA^Sec to investigate how Methanocaldococcus jannaschii PSTK distinguishes tRNA^Sec from tRNA^Ser. Unlike eukaryotic PSTK, the archaeal enzyme was found to recognize the acceptor stem rather than the length and secondary structure of the D-stem. While the D-arm and T-loop provide minor identity elements, the acceptor stem base pairs G2-C71 and C3-G70 in tRNA^Sec were crucial for discrimination from tRNA^Ser. Furthermore, the A5-U68 base pair in tRNA^Ser has some antideterminant properties for PSTK. Transplantation of these identity elements into the tRNA^Ser_UGA scaffold resulted in phosphorylation of the chimeric Ser-tRNA. The chimera was able to stimulate the ATPase activity of PSTK albeit at a lower level than tRNA^Sec, whereas tRNA^Ser did not. Additionally, the seryl moiety of Ser-tRNA^Sec is not required for enzyme recognition, as PSTK efficiently phosphorylated Thr-tRNA^Sec.     

A minimalist glutamyl-tRNA synthetase dedicated to aminoacylation of the tRNAAsp QUC anticodon

Escherichia coli encodes YadB, a protein displaying 34% identity with the catalytic core of glutamyl-tRNA synthetase but lacking the anticodon-binding domain. We show that YadB is a tRNA modifying enzyme that evidently glutamylates the queuosine residue, a modified nucleoside at the wobble position of the tRNA^Asp QUC anticodon. This conclusion is supported by a variety of biochemical data and by the inability of the enzyme to glutamylate tRNA^Asp isolated from an E.coli tRNA-guanosine transglycosylase minus strain deprived of the capacity to exchange guanosine 34 with queuosine. Structural mimicry between the tRNA^Asp anticodon stem and the tRNA^Glu amino acid acceptor stem in prokaryotes encoding YadB proteins indicates that the function of these tRNA modifying enzymes, which we rename glutamyl-Q tRNA^Asp synthetases, is conserved among prokaryotes.     

Association of tRNA acceptor identity with phosphate-sugar backbone interactions observed in the crystal structure of the Escherichia coli glutaminyl-tRNA synthetase-tRNA complex

We isolated several mutants with nucleotide substitutions in alanine tRNA (tRNA^Ala) that resulted in glutamine tRNA (tRNA^Gli) acceptor identity in Escherichia coli. These substitutions were in three regions of tRNA structure not previously associated with tRNA^Gln acceptor identity. Only the phosphate-sugar backbone moieties of these nucleotides interact with the enzyme in the previously determined X-ray crystal structure of the complex between tRNA^Gln and glutaminyl-tRNA synthetase. We conclude that these sequence-dependent phosphate-sugar backbone interactions contribute to tRNA^Gln identity, and argue that the interactions help communicate enzyme recognition of the anticodon to the acceptor end of the tRNA and the catalytic center of the enzyme.     

Structure of Escherichia coli Arginyl-tRNA Synthetase in Complex with tRNAArg: Pivotal Role of the D-loop

Aminoacyl-tRNA synthetases are essential components in protein biosynthesis. Arginyl-tRNA synthetase (ArgRS) belongs to the small group of aminoacyl-tRNA synthetases requiring cognate tRNA for amino acid activation. The crystal structure of Escherichia coli (Eco) ArgRS has been solved in complex with tRNA^Arg at 3.0-Å resolution. With this first bacterial tRNA complex, we are attempting to bridge the gap existing in structure–function understanding in prokaryotic tRNA^Arg recognition. The structure shows a tight binding of tRNA on the synthetase through the identity determinant A20 from the D-loop, a tRNA recognition snapshot never elucidated structurally. This interaction of A20 involves 5 amino acids from the synthetase. Additional contacts via U20a and U16 from the D-loop reinforce the interaction. The importance of D-loop recognition in EcoArgRS functioning is supported by a mutagenesis analysis of critical amino acids that anchor tRNA^Arg on the synthetase; in particular, mutations at amino acids interacting with A20 affect binding affinity to the tRNA and specificity of arginylation. Altogether the structural and functional data indicate that the unprecedented ArgRS crystal structure represents a snapshot during functioning and suggest that the recognition of the D-loop by ArgRS is an important trigger that anchors tRNA^Arg on the synthetase. In this process, A20 plays a major role, together with prominent conformational changes in several ArgRS domains that may eventually lead to the mature ArgRS:tRNA complex and the arginine activation. Functional implications that could be idiosyncratic to the arginine identity of bacterial ArgRSs are discussed.     

Human Cells Have a Limited Set of tRNA Anticodon Loop Substrates of the tRNA Isopentenyltransferase TRIT1 Tumor Suppressor

Human TRIT1 is a tRNA isopentenyltransferase (IPTase) homologue of Escherichia coli MiaA, Saccharomyces cerevisiae Mod5, Schizosaccharomyces pombe Tit1, and Caenorhabditis elegans GRO-1 that adds isopentenyl groups to adenosine 37 (i6A37) of substrate tRNAs. Prior studies indicate that i6A37 increases translation fidelity and efficiency in codon-specific ways. TRIT1 is a tumor suppressor whose mutant alleles are associated with cancer progression. We report the systematic identification of i6A37-containing tRNAs in a higher eukaryote, performed using small interfering RNA knockdown and other methods to examine TRIT1 activity in HeLa cells. Although several potential substrates contained the IPTase recognition sequence A36A37A38 in the anticodon loop, only tRNA^SerAGA, tRNA^SerCGA, tRNA^SerUGA, and selenocysteine tRNA with UCA (tRNA^[Ser]SecUCA) contained i6A37. This subset is a significantly more restricted than that for two distant yeasts (S. cerevisiae and S. pombe), the only other organisms comprehensively examined. Unlike the fully i6A37-modified tRNAs for Ser, tRNA^[Ser]SecUCA is partially (∼40%) modified. Exogenous selenium and other treatments that decreased the i6A37 content of tRNA^[Ser]SecUCA led to increased levels of the tRNA^[Ser]SecUCA. Of the human mitochondrion (mt)-encoded tRNAs with A36A37A38, only mt tRNAs tRNA^SerUGA and tRNA^TrpUCA contained detectable i6A37. Moreover, while tRNA^Ser levels were unaffected by TRIT1 knockdown, the tRNA^[Ser]SecUCA level was increased and the mt tRNA^SerUGA level was decreased, suggesting that TRIT1 may control the levels of some tRNAs as well as their specific activity.     

Identification of essential domains for Escherichia coli tRNA(leu) aminoacylation and amino acid editing using minimalist RNA molecules

Escherichia coli leucyl-tRNA synthetase (LeuRS) aminoacylates up to six different class II tRNA(leu) molecules. Each has a distinct anticodon and varied nucleotides in other regions of the tRNA. Attempts to construct a minihelix RNA that can be aminoacylated with leucine have been unsuccessful. Herein, we describe the smallest tRNA(leu) analog that has been aminoacylated to a significant extent to date. A series of tRNA(leu) analogs with various domains and combinations of domains deleted was constructed. The minimal RNA that was efficiently aminoacylated with LeuRS was one in which the anticodon stem-loop and variable arm stem-loop, but neither the D-arm nor T-arm, were deleted. Aminoacylation of this minimal RNA was abolished when the discriminator base A73 was replaced with C73 or when putative tertiary interactions between the D-loop and T-loop were disrupted, suggesting that these identity elements are still functioning in the minimized RNA. The various constructs that were significantly aminoacylated were also tested for amino acid editing by the synthetase. The anticodon and variable stem-loop domains were also dispensable for hydrolysis of the charged tRNA(leu) mimics. These results suggest that LeuRS may rely on identity elements in overlapping domains of the tRNA for both its aminoacylation and editing activities.     

Crystal structure of glutamyl-queuosine tRNAAsp synthetase complexed with L-glutamate: structural elements mediating tRNA-independent activation of glutamate and glutamylation of tRNAAsp anticodon

Glutamyl-queuosine tRNA^Asp synthetase (Glu-Q-RS) from Escherichia coli is a paralog of the catalytic core of glutamyl-tRNA synthetase (GluRS) that catalyzes glutamylation of queuosine in the wobble position of tRNA^Asp. Despite important structural similarities, Glu-Q-RS and GluRS diverge strongly by their functional properties. The only feature common to both enzymes consists in the activation of Glu to form Glu-AMP, the intermediate of transfer RNA (tRNA) aminoacylation. However, both enzymes differ by the mechanism of selection of the cognate amino acid and by the mechanism of its activation. Whereas GluRS selects l-Glu and activates it only in the presence of the cognate tRNA^Glu, Glu-Q-RS forms Glu-AMP in the absence of tRNA. Moreover, while GluRS transfers the activated Glu to the 3′ accepting end of the cognate tRNA^Glu, Glu-Q-RS transfers the activated Glu to Q34 located in the anticodon loop of the noncognate tRNA^Asp. In order to gain insight into the structural elements leading to distinct mechanisms of amino acid activation, we solved the three-dimensional structure of Glu-Q-RS complexed to Glu and compared it to the structure of the GluRS·Glu complex. Comparison of the catalytic site of Glu-Q-RS with that of GluRS, combined with binding experiments of amino acids, shows that a restricted number of residues determine distinct catalytic properties of amino acid recognition and activation by the two enzymes. Furthermore, to explore the structural basis of the distinct aminoacylation properties of the two enzymes and to understand why Glu-Q-RS glutamylates only tRNA^Asp among the tRNAs possessing queuosine in position 34, we performed a tRNA mutational analysis to search for the elements of tRNA^Asp that determine recognition by Glu-Q-RS. The analyses made on tRNA^Asp and tRNA^Asn show that the presence of a C in position 38 is crucial for glutamylation of Q34. The results are discussed in the context of the evolution and adaptation of the tRNA glutamylation system.