Evidence for interaction of an aminoacyl transfer RNA synthetase with a region important for the identity of its cognate transfer RNA

Recent experiments showed that a single base pair (G3:U70) in the amino acid acceptor helix is a major determinant for the identity of Escherichia coli alanine transfer RNA. Experiments reported here show that bound alanine tRNA synthetase protects (from ribonuclease attack) seven consecutive phosphodiester linkages on the 3'-side of the acceptor-T psi C helix (phosphates 65-71) and a few additional sites that are in scattered locations. There is no evidence for interaction of the enzyme with the anticodon, a sequence which can be varied without effect on recognition by alanine tRNA synthetase.     

Mutant aminoacyl-tRNA synthetase that compensates for a mutation in the major identity determinant of its tRNA

A single G3.U70 base pair in the acceptor helix is the major determinant for the identity of alanine transfer RNAs (Hou & Schimmel, 1988). Introduction of this base pair into foreign tRNA sequences confers alanine acceptance on them. Moreover, small RNA helices with as few as seven base pairs can be aminoacylated with alanine, provided that they encode the critical base pair (Francklyn & Schimmel, 1989). Alteration of G3.U70 to G3.C70 abolishes aminoacylation with alanine in vivo and in vitro. We describe here the mutagenesis and selection of a single point mutation in Escherichia coli Ala-tRNA synthetase that compensates for a G3.C70 mutation in tRNAAla. The mutation maps to a region previously implicated as proximal to the acceptor end of the bound tRNA. In contrast to the wild-type enzyme, the mutant charges small RNA helices that encode a G3.C70 base pair. However, the mutant enzyme retains specificity for alanine tRNA and can serve as the sole source of Ala-tRNA synthetase in vivo. The results demonstrate the capacity of an aminoacyl-tRNA synthetase to compensate through a single amino acid substitution for mutations in the major determinant of its cognate tRNA.     

Evidence that a major determinant for the identity of a transfer RNA is conserved in evolution

We observed recently that a single G3.U70 base pair in the amino acid acceptor stem of an Escherichia coli alanine tRNA is a major determinant for its identity. Inspection of tRNA sequences shows that G3.U70 is unique to alanine in E. coli and is present in eucaryotic cytoplasmic alanine tRNAs. We show here that single nucleotide changes of G3.U70 to A3.U70 or to G3.C70 eliminate in vitro aminoacylation of an insect and of a human alanine tRNA by the respective homologous synthetase. Compared to the influence of G3.U70, other sequence variations in tRNAAla have a relatively small effect on aminoacylation by the insect and human enzymes. In addition, while these eucaryotic tRNAs have nucleotide differences from E. coli alanine tRNA, they are heterologously charged only with alanine when expressed in E. coli. The results indicate a functional role for G3.U70 that is conserved in evolution. They also suggest that the sequence differences between E. coli and the eucaryotic alanine tRNAs at sites other than the conserved G3.U70 do not create major determinants for recognition by any other bacterial enzyme.     

A single base pair dominates over the novel identity of an Escherichia coli tyrosine tRNA in Saccharomyces cerevisiae.

The Escherichia coli su+3 tyrosine tRNA was shown recently to be a leucine-specific tRNA in Saccharomyces cerevisiae. This finding raises the possibility that some determinants for tRNA identity in E. coli may be different in S. cerevisiae. To investigate whether the fungal system is sensitive to the major determinant for alanine acceptance in E. coli, a single G3 . U70 base pair was introduced into the acceptor helix of the su+3 tyrosine tRNA. This substitution converts the identity of the E. coli suppressor in S. cerevisiae from leucine to alanine. Thus, as in E. coli, G3 . U70 is a strong determinant for alanine acceptance that can dominate over other features in a tRNA that might be recognized by alternative charging enzymes.     

Functional compensation of a recognition-defective transfer RNA by a distal base pair substitution.

A single G3:U70 base pair in the acceptor helix is the major determinant of alanine acceptance in alanine transfer RNAs. Transfer of this base pair into other transfer RNAs confers alanine acceptance. A G3:C70 substitution eliminates alanine acceptance in vivo and in vitro. In this work, a population of mutagenized G3:C70 alanine tRNA amber suppressors was subjected to a selection for mutations that compensate for the inactivating G3:C70 substitution. No compensatory mutations located in the acceptor helix were obtained. Instead, a U27:U43 substitution that replaced the wild-type C27:G43 in the anticodon stem created a U27:U43/G3:C70 mutant alanine tRNA that inserts alanine at amber codons in vivo. The U27:U43 substitution is at a location where previous footprinting work established an RNA-protein contact. Thus, this mutation may act by functionally coupling a distal part of the tRNA structure to the active site.     

Functional compensation by particular nucleotide substitutions of a critical G*U wobble base-pair during aminoacylation of transfer RNA

Expression of the genetic code depends on precise tRNA aminoacylation by cognate aminoacyl-tRNA synthetase enzymes. The G.U wobble base-pair in the acceptor helix of Escherichia coli alanine tRNA is the primary aminoacylation determinant of this molecule. Previous work on the process of synthetase recognition of the G.U pair showed that replacing G.U by a G.C Watson-Crick base-pair inactivates alanine acceptance by the tRNA, but that C.A and G.A wobble pair replacements preserve acceptance. Work by another group reported that the effects of a G.C replacement were reversed by a distal wobble base-pair in the anticodon helix. This result is potentially interesting because it suggests that distant regions in alanine tRNA are functionally coupled during synthetase recognition and more generally because recognition determinants of many other tRNAs lie in both the acceptor helix and anticodon helix region. Here, we have conducted an extensive in vivo analysis of the distal wobble pair in alanine tRNA and report that it does not behave like a compensating mutation. Restoration of alanine acceptance was not detected even when the synthetase enzyme was overproduced. We discuss the previous experimental evidence and suggest how the distal wobble pair was incorrectly analyzed. The available data indicate that all principal recognition determinants of alanine tRNA lie in the molecule's acceptor helix.     

A nucleotide that enhances the charging of RNA minihelix sequence variants with alanine.

We showed earlier that a single G3.U70 base pair within the amino acid acceptor helix is a major determinant of the identity of tRNA(Ala). In addition, we demonstrated that an RNA hairpin minihelix that recreates the 12 base pair acceptor-T psi C stem of tRNA(Ala) is also aminoacylated in a G3.U70-dependent manner. Determinants for efficient aminoacylation at pH 7.5 have been further investigated with minihelix substrates that have sequence variations at 3.70 and other locations. Although a U,U mismatch and other 3.70 nucleotide alternatives to G.U were recently proposed by others as also important for alanine acceptance, neither that mismatch nor any of four other 3.70 nucleotide combinations confer aminoacylation in vitro with alanine, even with substrate levels of enzyme. In contrast, permutations of the so-called discriminator nucleotide N73 (at position 73) strongly modulate, but do not block, aminoacylation of those substrates that encode G3.U70. In particular, the efficiency of G3.U70-dependent aminoacylation with alanine is strongly enhanced by having the wild-type A73. The effect of N73 alone can explain most of the difference in aminoacylation efficiency of a G3.U70-containing tRNA and a minihelix substrate whose sequences vary significantly from their tRNA(Ala) counterparts. Comparison with earlier work suggests that the substantial modulating effect of N73 is partly or completely obscured when N73 tRNA variants are expressed as amber suppressors in vivo.     

A single base pair affects binding and catalytic parameters in the molecular recognition of a transfer RNA

A single G3.U70 base pair in the acceptor helix is a major determinant of the identity of an alanine transfer RNA. Alteration of this base pair to A.U or G.C prevents aminoacylation with alanine. We show here that, at approximate physiological conditions (pH 7.5, 37 degrees C), high concentrations of the mutant A3.U70 species do not inhibit aminoacylation of a wild-type alanine tRNA. The observation suggests that, under these conditions, the G3 to A3 substitution increases Km for tRNA by more than 30-fold. Other experiments at pH 7.5 show that no aminoacylation of A3.U70, G3.C70, or U3.G70 mutant tRNAs occurs with substrate levels of enzyme. This suggests that kcat for these mutant tRNAs is sharply reduced as well and that the catalytic defect is not due to slow release of charged mutant tRNAs from the enzyme. Investigations were also done at pH 5.5, where association of tRNAs with synthetases is generally stronger and where binding can be conveniently measured apart from aminoacylation. Under these conditions, the binding of the A3.U70 and G3.C70 species is readily detected and is only 3-5-fold weaker than the binding of the wild-type tRNA. Although the A3.U70 species was demonstrated to compete with the wild-type tRNA for the same site on the enzyme, no aminoacylation could be detected. Thus, even when conditions are adjusted to obtain strong competitive binding, a sharp reduction in kcat prevents aminoacylation of a tRNA(Ala) species with a substitution at position 3.70.     

Identification of discriminator base atomic groups that modulate the alanine aminoacylation reaction

Specific aminoacylation of tRNAs involves activation of an amino acid with ATP followed by amino acid transfer to the tRNA. Previous work showed that the transfer of alanine from Escherichia coli alanyl-tRNA synthetase to a cognate RNA minihelix involves a transition state sensitive to changes in the tRNA acceptor stem. Specifically, the "discriminator" base at position 73 of minihelix(Ala) is a critical determinant of the transfer step of aminoacylation. This single-stranded nucleotide has previously been shown by solution NMR to be stacked predominantly onto G(1) of the first base pair of the alanine acceptor stem helix. In this work, RNA duplex(Ala) variants were prepared to investigate the role of specific discriminator base atomic groups in aminoacylation catalytic efficiency. Results indicate that the purine structure appears to be important for stabilization of the transition state and that major groove elements are more critical than those located in the minor groove. This result is in accordance with the predicted orientation of a class II synthetase at the end of the acceptor helix. In particular, substitution of the exocyclic amino group of A(73) with a keto-oxygen resulted in negative discrimination at this site. Taken together, these new results are consistent with the involvement of major groove atomic groups of the discriminator base in the formation of the transition state for the amino acid transfer step.     

Translocation within the acceptor helix of a major tRNA identity determinant

The genetic code is defined by the specific aminoacylations of tRNAs by aminoacyl-tRNA synthetases. Although the synthetases are widely conserved through evolution, aminoacylation of a given tRNA is often system specific-a synthetase from one source will not acylate its cognate tRNA from another. This system specificity is due commonly to variations in the sequence of a critical tRNA identity element. In bacteria and the cytoplasm of eukaryotes, an acceptor stem G3:U70 base pair marks a tRNA for aminoacylation with alanine. In contrast, Drosophila melanogaster (Dm) mitochondrial (mt) tRNA(Ala) has a G2:U71 but not a G3:U70 pair. Here we show that this translocated G:U and the adjacent G3:C70 are major determinants for recognition by Dm mt alanyl-tRNA synthetase (AlaRS). Additionally, G:U at the 3:70 position serves as an anti-determinant for Dm mt AlaRS. Consequently, the mitochondrial enzyme cannot charge cytoplasmic tRNA(Ala). All insect mitochondrial AlaRSs appear to have split apart recognition of mitochondrial from cytoplasmic tRNA(Ala) by translocation of G:U. This split may be essential for preventing introduction of ambiguous states into the genetic code.     

Threonyl-tRNA synthetase of archaea: importance of the discriminator base in the aminoacylation of threonine tRNA.

To investigate the contribution of the discriminator base of archaeal tRNA(Thr) in aminoacylation by threonyl-tRNA synthetase (ThrRS), cross-species aminoacylation between Escherichia coli and Haloferax volcanii, halophilic archaea, was studied. It was found that E. coli ThrRS threonylated the H. volcanii tRNA(Thr) but that E. coli threonine tRNA was not aminoacylated by H. volcanii ThrRS. Results of a threonylation experiment using in vitro mutants of E. coli threonine tRNA showed that only the mutant tRNA(Thr) having U73 was threonylated by H. volcanii ThrRS. These findings indicate that the discriminator base U73 of H. volcanii tRNA(Thr) is a strong determinant for the recognition by ThrRS.     

Structure of the acceptor stem of Escherichia coli tRNA Ala: role of the G3.U70 base pair in synthetase recognition.

The fidelity of translation of the genetic code depends on accurate tRNA aminoacylation by cognate aminoacyl-tRNA synthetases. Thus, each tRNA has specificity not only for codon recognition, but also for amino acid identity; this aminoacylation specificity is referred to as tRNA identity. The primary determinant of the acceptor identity of Escherichia coli tRNAAlais a wobble G3.U70 pair within the acceptor stem. Despite extensive biochemical and genetic data, the mechanism by which the G3.U70 pair marks the acceptor end of tRNAAla for aminoacylation with alanine has not been clarified at the molecular level. The solution structure of a microhelix derived from the tRNAAla acceptor end has been determined at high precision using a very extensive set of experimental constraints (approximately 32 per nt) obtained by heteronuclear multidimensional NMR methods. The tRNAAla acceptor end is overall similar to A-form RNA, but important differences are observed. The G3.U70 wobble pair distorts the conformation of the phosphodiester backbone and presents the functional groups of U70 in an unusual spatial location. The discriminator base A73 has extensive stacking overlap with G1 within the G1.C72 base pair at the end of the double helical stem and the -CCA end is significantly less ordered than the rest of the molecule.     

Positional recognition of a tRNA determinant dependent on a peptide insertion

The crystal structure of a catalytic fragment of Aquifex aeolicus AlaRS and additional data suggest how the critical G3:U70 identity element of its cognate tRNA acceptor stem is recognized. Though this identity element is conserved from bacteria to the cytoplasm of eukaryotes, Drosophila melanogaster mitochondrial (Dm mt) tRNA(Ala) contains a G:U base pair that has been translocated to the adjacent 2:71 position. This G2:U71 is the major determinant for identity of Dm mt tRNA(Ala). Sequence alignments showed that Dm mt AlaRS is differentiated from G3:U70-recognizing AlaRSs by an insertion of 27 amino acids in the region of the protein that contacts the acceptor stem. Precise deletion of this insertion from Dm mt AlaRS gave preferential recognition to a G3:U70-containing substrate. Larger or smaller deletions were ineffective. The crystal structure of the orthologous A. aeolicus protein places this insertion on the surface, where it can act as a hinge that provides positional switching of G:U recognition.     

RNA tetraloops as minimalist substrates for aminoacylation.

Previous work established that seven-base-pair hairpin microhelices with sequences based on the acceptor stems of alanine, glycine, methionine, and histidine tRNAs can be aminoacylated specifically with their cognate amino acids. To obtain "minimalist" substrates with fewer base pairs, we took advantage of the high thermodynamic stability of RNA tetraloop motifs that are found in ribosomal RNAs. We show here that rationally designed RNA tetraloops with as few as four base pairs are substrates for aminoacylation. Major nucleotide determinants for recognition by the class II synthetases were incorporated into each of the respective tetraloop substrates, resulting in specific aminoacylation by the alanine, glycine, and histidine tRNA synthetases. An analysis of the kinetics of aminoacylation shows that, for the alanine system, the majority of the transition-state stabilization provided by the synthetase-tRNA interaction is reproduced by the interaction of the synthetase with nucleotides in its minimalist tetraloop substrate. In an extension of this work, we also observed specific aminoacylation with the class I methionine tRNA synthetase of RNA tetraloops based on sequences in the acceptor stem of methionine tRNA. Thus, the results demonstrate four different examples where specific aminoacylation is directed by sequences/structures contained in less than half of a turn of an RNA helix.     

Specific interaction between anticodon nuclease and the tRNA(Lys) wobble base

The bacterial tRNA(Lys)-specific PrrC-anticodon nuclease cleaves its natural substrate 5' to the wobble base, yielding 2',3'-cyclic phosphate termini. Previous work has implicated the anticodon of tRNA(Lys) as a specificity element and a cluster of amino acid residues at the carboxy-proximal half of PrrC in its recognition. We further examined these assumptions by assaying unmodified and hypomodified derivatives of tRNA(Lys) as substrates of wild-type and mutant alleles of PrrC. The data show, first, that the anticodon sequence and wobble base modifications of tRNA(Lys) play major roles in the interaction with anticodon nuclease. Secondly, a specific contact between the substrate recognition site of PrrC and the tRNA(Lys) wobble base is revealed by PrrC missense mutations that suppress the inhibitory effects of wobble base modification mutations. Thirdly, the data distinguish between the anticodon recognition mechanisms of PrrC and lysyl-tRNA synthetase.     

The Enzymatic Paradox of Yeast Arginyl-tRNA Synthetase: Exclusive Arginine Transfer Controlled by a Flexible Mechanism of tRNA Recognition

Identity determinants are essential for the accurate recognition of transfer RNAs by aminoacyl-tRNA synthetases. To date, arginine determinants in the yeast Saccharomyces cerevisiae have been identified exclusively in vitro and only on a limited number of tRNA Arginine isoacceptors. In the current study, we favor a full cellular approach and expand the investigation of arginine determinants to all four tRNA Arg isoacceptors. More precisely, this work scrutinizes the relevance of the tRNA nucleotides at position 20, 35 and 36 in the yeast arginylation reaction. We built 21 mutants by site-directed mutagenesis and tested their functionality in YAL5, a previously engineered yeast knockout deficient for the expression of tRNA Arg CCG. Arginylation levels were also monitored using Northern blot. Our data collected in vivo correlate with previous observations. C35 is the prominent arginine determinant followed by G36 or U36 (G/U36). In addition, although there is no major arginine determinant in the D loop, the recognition of tRNA Arg ICG relies to some extent on the nucleotide at position 20. This work refines the existing model for tRNA Arg recognition. Our observations indicate that yeast Arginyl-tRNA synthetase (yArgRS) relies on distinct mechanisms to aminoacylate the four isoacceptors. Finally, according to our refined model, yArgRS is able to accommodate tRNA Arg scaffolds presenting N34, C/G35 and G/A/U36 anticodons while maintaining specificity. We discuss the mechanistic and potential physiological implications of these findings.