Yeast arginyl-tRNA Synthetase Research Articles

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.

Site-specific incorporation of arginine analogs into proteins using arginyl-tRNA synthetase

Arginine analogs were incorporated site-specifically into proteins using an in vitro translation system. In this system, mRNAs containing a CGGG codon were translated by an aminoacyl-tRNACCCG, which was charged with arginine analogs using yeast arginyl-tRNA synthetase. NG-monomethyl-l-arginine, l-citrulline and l-homoarginine were incorporated successfully into proteins using this method. The influence of arginine monomethylation in histone H3 on the acetylation of lysine residues by histone acetyltransferase hGCN5 was investigated, and the results demonstrated that K9 acetylation was suppressed by the methylation of R8 and R17 but not by R26 methylation. K18 acetylation was not affected by the methylation of R8, R17 and R26. This site-specific modification strategy provides a way to explore the roles of post-translational modifications in the absence of heterogeneity due to other modifications.

Limited set of amino acid residues in a class Ia aminoacyl-tRNA synthetase is crucial for tRNA binding.

The aim of this work was to characterize crucial amino acids for the aminoacylation of tRNA(Arg) by yeast arginyl-tRNA synthetase. Alanine mutagenesis was used to probe all the side chain mediated interactions that occur between tRNA(Arg2)(ICG) and ArgRS. The effects of the substitutions were analyzed in vivo in an ArgRS-knockout strain and in vitro by measuring the aminoacylation efficiencies for two distinct tRNA(Arg) isoacceptors. Nine mutants that generate lethal phenotypes were identified, suggesting that only a limited set of side chain mediated interactions is essential for tRNA recognition. The majority of the lethal mutants was mapped to the anticodon binding domain of ArgRS, a helix bundle that is characteristic for class Ia synthetases. The alanine mutations induce drastic decreases in the tRNA charging rates, which is correlated with a loss in affinity in the catalytic site for ATP. One of those lethal mutations corresponds to an Arg residue that is strictly conserved in all class Ia synthetases. In the known crystallographic structures of complexes of tRNAs and class Ia synthetases, this invariant Arg residue stabilizes the idiosyncratic conformation of the anticodon loop. This paper also highlights the crucial role of the tRNA and enzyme plasticity upon binding. Divalent ions are also shown to contribute to the induced fit process as they may stabilize the local tRNA-enzyme interface. Furthermore, one lethal phenotype can be reverted in the presence of high Mg(2+) concentrations. In contrast with the bacterial system, in yeast arginyl-tRNA synthetase, no lethal mutation has been found in the ArgRS specific domain recognizing the Dhu-loop of the tRNA(Arg). Mutations in this domain have no effects on tRNA(Arg) aminoacylation, thus confirming that Saccharomyces cerevisiae and other fungi belong to a distinct class of ArgRS.

TRNA aminoacylation by arginyl-tRNA synthetase: induced conformations during substrates binding.

The 2.2 A crystal structure of a ternary complex formed by yeast arginyl-tRNA synthetase and its cognate tRNA(Arg) in the presence of the L-arginine substrate highlights new atomic features used for specific substrate recognition. This first example of an active complex formed by a class Ia aminoacyl-tRNA synthetase and its natural cognate tRNA illustrates additional strategies used for specific tRNA selection. The enzyme specifically recognizes the D-loop and the anticodon of the tRNA, and the mutually induced fit produces a conformation of the anticodon loop never seen before. Moreover, the anticodon binding triggers conformational changes in the catalytic center of the protein. The comparison with the 2.9 A structure of a binary complex formed by yeast arginyl-tRNA synthetase and tRNA(Arg) reveals that L-arginine binding controls the correct positioning of the CCA end of the tRNA(Arg). Important structural changes induced by substrate binding are observed in the enzyme. Several key residues of the active site play multiple roles in the catalytic pathway and thus highlight the structural dynamics of the aminoacylation reaction.

The tRNA-dependent activation of arginine by arginyl-tRNA synthetase requires inter-domain communication

The tRNA-dependent amino acid activation catalyzed by mammalian arginyl-tRNA synthetase has been characterized. A conditional lethal mutant of Chinese hamster ovary cells that exhibits reduced arginyl-tRNA synthetase activity (Arg-1), and two of its derived revertants (Arg-1R4 and Arg-1R5) were analyzed at the structural and functional levels. A single nucleotide change, resulting in a Cys to Tyr substitution at position 599 of arginyl-tRNA synthetase, is responsible for the defective phenotype of the thermosensitive and arginine hyper-auxotroph Arg-1 cell line. The two revertants have a single additional mutation resulting in a Met222 to Ile change for Arg-1R4 or a Tyr506 to Ser change for Arg-1R5. The corresponding mutant enzymes were expressed in yeast and purified. The Cys599 to Tyr mutation affects both the thermal stability of arginyl-tRNA synthetase and the kinetic parameters for arginine in the ATP-PP i exchange and tRNA aminoacylation reactions. This mutation is located underneath the floor of the Rossmann fold catalytic domain characteristic of class 1 aminoacyl-tRNA synthetases, near the end of a long helix belonging to the α-helix bundle C-terminal domain distinctive of class 1a synthetases. For the Met222 to Ile revertant, there is very little effect of the mutation on the interaction of arginyl-tRNA synthetase with either of its substrates. However, this mutation increases the thermal stability of arginyl-tRNA synthetase, thereby leading to reversion of the thermosensitive phenotype by increasing the steady-state level of the enzyme in vivo. In contrast, for the Arg-1R5 cell line, reversion of the phenotype is due to an increased catalytic efficiency of the C599Y/Y506S double mutant as compared to the initial C599Y enzyme. In light of the location of the mutations in the 3D structure of the enzyme modeled using the crystal structure of the closely related yeast arginyl-tRNA synthetase, the kinetic analysis of these mutants suggests that the obligatory tRNA-induced activation of the catalytic site of arginyl-tRNA synthetase involves interdomain signal transduction via the long helices that build the tRNA-binding domain of the enzyme and link the site of interaction of the anticodon domain of tRNA to the floor of the active site.

TRNAArgrecognition by yeast Arginyl-tRNA synthetase: crystal structure of the yeast arginyl-tRNA synthetase-yeast tRNAArgcomplex at 2.2 Å

tRNA^Argrecognition by yeast Arginyl-tRNA synthetase: crystal structure of the yeast arginyl-tRNA synthetase-yeast tRNA^Argcomplex at 2.2 Å

Crystallization and preliminary X-ray crystallographic analysis of yeast arginyl-tRNA synthetase-yeast tRNAArg complexes.

Three different crystal forms of complexes between arginyl-tRNA synthetase from the yeast Saccharomyces cerevisae (yArgRS) and the yeast second major tRNA(Arg) (tRNA(Arg)(ICG)) isoacceptor have been crystallized by the hanging-drop vapour-diffusion method in the presence of ammonium sulfate. Crystal form II, which diffracts beyond 2.2 A resolution at the European Synchrotron Radiation Facility ID14-4 beamline, belongs to the orthorhombic space group P2(1)2(1)2, with unit-cell parameters a = 129.64, b = 107.47, c = 71. 38 A. This crystal form presents the highest resolution obtained for an active form of an aminoacyl-tRNA synthetase-tRNA complex. The estimated V(m) of 2.6 A(3) Da(-1) indicates one molecule of complex in the asymmetric unit. The three crystal forms were solved by the molecular-replacement method using the coordinates of the free yArgRS.

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.

Mirror image alternative interaction patterns of the same tRNA with either class I arginyl-tRNA synthetase or class II aspartyl-tRNA synthetase.

Gene cloning, overproduction and an efficient purification protocol of yeast arginyl-tRNA synthetase (ArgRS) as well as the interaction patterns of this protein with cognate tRNAArgand non-cognate tRNAAspare described. This work was motivated by the fact that the in vitro transcript of tRNAAspis of dual aminoacylation specificity and is not only aspartylated but also efficiently arginylated. The crystal structure of the complex between class II aspartyl-tRNA synthetase (AspRS) and tRNAAsp, as well as early biochemical data, have shown that tRNAAspis recognized by its variable region side. Here we show by footprinting with enzymatic and chemical probes that transcribed tRNAAspis contacted by class I ArgRS along the opposite D arm side, as is homologous tRNAArg, but with idiosyncratic interaction patterns. Besides protection, footprints also show enhanced accessibility of the tRNAs to the structural probes, indicative of conformational changes in the complexed tRNAs. These different patterns are interpreted in relation to the alternative arginine identity sets found in the anticodon loops of tRNAArgand tRNAAsp. The mirror image alternative interaction patterns of unmodified tRNAAspwith either class I ArgRS or class II AspRS, accounting for the dual identity of this tRNA, are discussed in relation to the class defining features of the synthetases. This study indicates that complex formation between unmodified tRNAAspand either ArgRS and AspRS is solely governed by the proteins.

Arginine aminoacylation identity is context-dependent and ensured by alternate recognition sets in the anticodon loop of accepting tRNA transcripts.

Yeast arginyl-tRNA synthetase recognizes the non-modified wild-type transcripts derived from both yeast tRNA(Arg) and tRNA(Asp) with equal efficiency. It discriminates its cognate natural substrate, tRNA(Arg), from non-cognate tRNA(Asp) by a negative discrimination mechanism whereby a single methyl group acts as an anti-determinant. Considering these facts, recognition elements responsible for specific arginylation in yeast have been searched by studying the in vitro arginylation properties of a series of transcripts derived from yeast tRNA(Asp), considered as an arginine isoacceptor tRNA. In parallel, experiments on similar tRNA(Arg) transcripts were performed. Unexpectedly, in the tRNA(Arg) context, arginylation is basically linked to the presence of residue C35, whereas in the tRNA(Asp) context, it is deeply related to that of C36 and G37 but is insensitive to the nucleotide at position 35. Each of these nucleotides present in one host, is absent in the other host tRNA. Thus, arginine identity is dependent on two different specific recognition sets according to the tRNA framework investigated.

Aspartate identity of transfer RNAs

Structure/function relationships accounting for specific tRNA charging by class II aspartyl-tRNA synthetases from Saccharomyces cerevisiae, Escherichia coli and Thermus thermophilus are reviewed. Effects directly linked to tRNA features are emphasized and aspects about synthetase contribution in expression of tRNA Asp identity are also covered. Major identity nucleotides conferring aspartate specificity to yeast, E coli and T thermophilus tRNAs comprise G34, U35, C36, C38 and G73, a set of nucleotides conserved in tRNA Asp molecules of other biological origin. Aspartate specificity can be enhanced by negative discrimination preventing, eg mischarging of native yeast tRNA Asp by yeast arginyl-tRNA synthetase. In the yeast system crystallography shows that identity nucleotides are in contact with identity amino acids located in the catalytic and anticodon binding domains of the synthetase. Specificity of RNA/protein interaction involves a conformational change of the tRNA that optimizes the H-bonding potential of the identity signals on both partners of the complex. Mutation of identity nucleotides leads to decreased aspartylation efficiencies accompanied by a loss of specific H-bonds and an altered adaptation of tRNA on the synthetase. Species-specific characteristics of aspartate systems are the number, location and nature of minor identity signals. These features and the structural variations in aspartate tRNAs and synthetases are correlated with mechanistic differences in the aminoacylation reactions catalyzed by the various aspartyl-tRNA synthetases. The reality of the aspartate identity set is verified by its functional expression in a variety of RNA frameworks. Inversely a number of identities can be expressed within a tRNA Asp framework. From this emerged the concept of the RNA structural frameworks underlying expression of identities which is illustrated with data obtained with engineered tRNAs. Efficient aspartylation of minihelices is explained by the primordial role of G73. From this and other considerations it is suggested that aspartate identity appeared early in the history of tRNA aminoacylation systems.

Study of the interaction of yeast arginyl-tRNA synthetase with yeast tRNAArg2 and tRNAArg3 by partial digestions with cobra venom ribonuclease.

Yeast tRNAArg2 and tRNAArg3 are two isoacceptors which show similar V and Km for yeast arginyl-tRNA synthetase despite important differences in their primary structures. Fragments resulting from the partial digestion of 3' or 5' end-labelled tRNAArg2 and tRNAArg3 in the presence or absence of arginyl-tRNA synthetase by cobra venom ribonuclease, an enzyme which cuts preferentially in double-stranded regions, were analysed by electrophoresis on polyacrylamide gels. In the absence of arginyl-tRNA synthetase, major cuts were observed in tRNAArg2 and tRNAArg3 at the end of the 3' part of the acceptor stem and in the 5' part of the anticodon stem, whereas the 5' part of the acceptor stem and the 3' part of the anticodon stem are only slightly cleaved. The D and the T stems are almost fully resistant to cobra venom ribonuclease attack confirming the strong tertiary structural organization of this region. In the presence of arginyl-tRNA synthetase the two or three last sites of the 3' halves of the acceptor stems and the sites in the 3' halves of the anticodon stems are almost completely protected against ribonuclease hydrolysis in both tRNAs; 31-69% protection of the sites located in the 5' halves of the anticodon stem is also observed. However, the cleavage levels are enhanced for the three head positions in the 3' halves of the acceptor stems and a new cut appears at the first position of this region in the case of tRNAArg3. The similarity of the protection patterns of tRNAArg2 and tRNAArg3 suggests that both molecules interact in nearly the same manner with arginyl-tRNA synthetase, which in turn implies great similarities in their tertiary structure when involved in the complex. If this tertiary organization is like that described for tRNAPhe, all protected sites are located in the inside of its L-shaped model.

Arginyl-tRNA Synthetase fromEscherichia coliK12: Specificity with Regard to ATP Analogs and their Magnesium Complexes

Fifteen analogs of ATP have been tested in the ATP/PPi pyrophosphate exchange and the aminoacylation of arginyl-tRNA synthetase from E. coli K12. Six compounds are substrates in both reactions, whereas seven of the triphosphates were inhibitors for both reactions. The Km, V and Ki values have been determined. The enzyme is less specific against base modifications of the ATP molecule than arginyl tRNA synthetase from baker's yeast in the aminoacylation and is inhibited by more base-modified compounds in the ATP/PPi exchange. The enzyme accepts 3'-deoxy-ATP as substrate and is inhibited by 2'-methoxy-ATP, whereas the reversed observation is made for the yeast arginyl-tRNA synthetase. The stoichiometry and association constants of complexes formed by six ATP analogs (four substrates and two inhibitors) and magnesium ions were investigated; five analogs form 1:1 complexes, one analog (3'-deoxy-ATP) binds two magnesium ions. The enzyme must accept different complexes formed with one or two magnesium ions as substrate, which must be different in structure from complexes proposed in literature.

Interaction of yeast arginyl-tRNA synthetase and aspartyl-tRNA synthetase with Blue-Dextran sepharose: Assignement of the Blue-Dextran binding site on the synthetases

Yeast arginyl-tRNA synthetase and aspartyl-tRNA synthetase like nucleotidyl transferases previously investigated interact with the Blue-Dextran-Sepharose affinity ligand through their tRNA binding domain: the enzymes are readily displaced from the affinity column by their cognate tRNAs but not by ATP or a mixture of ATP and the cognate amino acid in contrast to other aminoacyl-tRNA synthetases. In the absence of Mg ++, the arginyl-tRNA synthetase can be dissociated from the column by tRNA Asp and tRNA Phe which have been shown to be able to form a complex with the synthetase, but in presence of Mg ++ the elution is only obtained by the specific tRNA. The procedure described here can thus be used: (i) to detect polynucleotide binding sites in a protein; (ii) to estimate the relative affinities of different tRNAs for a purified synthetase; (iii) to purify an aminoacyl-tRNA synthetase by selective elution with the cognate tRNA.

Structural studies on aminoacyl-tRNA synthetases A tentative correlation between the subunit size and the occurrence of repeated sequences

Recent studies have shown that those synthetases with subunits greater than 85 000 daltons contain extensive repeated sequences, whilst those with small subunits (40 000 daltons) do not. We have undertaken a comparative study of four aminoacyl-tRNA synthetases (glutamyl-, arginyl-, valyl-, and phenylalanyl-tRNA synthetases) with subunit sizes ranging from 56 000 to 130 000 daltons in an attempt to correlate the occurrence and extent of the repeats with the length of the polypeptide chain. Our results show that monomeric glutamyl-tRNA synthetase from Escherichia coli (56 000 daltons) contains few repeated sequences, whereas both subunits of yeast phenylalanyl-tRNA synthetase (α, 73 000 daltons; β, 62 000 daltons) and yeast arginyl-tRNA synthetase (74 000 daltons) do have a significant amount of repeats. Thus 56 000 daltons appears to be the minimum size compatible with the existence of such repeats.