Initial position of aminoacylation of individual Escherichia coli, yeast, and calf liver transfer RNAs.

Transfer RNAs from Escherichia coli, yeast (Sacharomyces cerevisiae), and calf liver were subjected to controlled hydrolysis with venom exonuclease to remove 3'-terminal nucleotides, and then reconstructed successively with cytosine triphosphate (CTP) and 2'- or 3'-deoxyadenosine 5'-triphosphate in the presence of yeast CTP(ATP):tRNA nucleotidyltransferase. The modified tRNAs were purified by chromatography on DBAE-cellulose or acetylated DBAE-cellulose and then utilized in tRNA aminoacylation experiments in the presence of the homologous aminoacyl-tRNA synthetase activities. The E. coli, yeast, and calf liver aminoacyl-tRNA synthetases specific for alanine, glycine, histidine, lysine, serine, and threonine, as well as the E. coli and yeast prolyl-tRNA synthetases and the yeast glutaminyl-tRNA synthetase utilized only those homologous modified tRNAs terminating in 2'-deoxyadenosine (i.e., having an available 3'-OH group). This is interpreted as evidence that these aminoacyl-tRNA synthetases normally aminoacylate their unmodified cognate tRNAs on the 3'-OH group. The aminoacyl-tRNA synthetases from all three sources specific argining, isoleucine, leucine, phenylalanine, and valine, as well as the E. coli and yeast enzymes specific for methionine and the E. coli glutamyl-tRNA synthetase, used as substrates exclusively those tRNAs terminating in 3'-deoxyadenosine. Certain aminoacyl-tRNA synthetases, including the E. coli, yeast, and calf liver asparagine and tyrosine activating enzymes, the E. coli and yeast cysteinyl-tRNA synthetases, and the aspartyl-tRNA synthetase from yeast, utilized both isomeric tRNAs as substrates, although generally not at the same rate. While the calf liver aspartyl- and cysteinyl-tRNA synthetases utilized only the corresponding modified tRNA species terminating in 2'-deoxyadenosine, the use of a more concentrated enzyme preparation might well result in aminoacylation of the isomeric species. The one tRNA for which positional specificity does seem to have changed during evolution is tryptophan, whose E. coli aminoacyl-tRNA synthetase utilized predominantly the cognate tRNA terminating in 3'-deoxyadenosine, while the corresponding yeast and calf liver enzymes were found to utilize predominantly the isomeric tRNAs terminating in 2'-deoxyadenosine. The data presented indicate that while there is considerable diversity in the initial position of aminoacylation of individual tRNA isoacceptors derived from a single source, positional specificity has generally been conserved during the evolution from a prokaryotic to mammalian organism.     

Loss of positional specificity in the aminoacylation of Escherichia coli tRNAGly

The positional specificity in the aminoacylation of Escherichia coli tRNAGly by its cognate aminoacyl-tRNA synthetase has been studied using tRNAGlys terminating in 2'- or 3'-deoxyadenosine under conditions believed to alter tRNA conformation. Although E. coli tRNAGly terminating in 3'-deoxyadenosine has been reported not to be a good substrate for activation by the homologous glycyl-tRNA synthetase, by systematic variation of the conditions employed for aminoacylation it was possible to activate this tRNA to essentially the same extent as unmodified tRNAGly. Activation of tRNAGly terminating in 3'-deoxyadenosine was carried out optimally at 45 degrees C in an incubation mixture containing 0.3-0.4 M NaCl; 10% methanol, ethanol, and dimethyl sulfoxide were found to facilitate activation of the modified tRNA. Interestingly, the conditions employed to enhance activation of this modified tRNAGly had no effect on the activation of unmodified tRNAGly or tRNAGly terminating in 2'-deoxyadenosine. These experiments afford insight into the activation of tRNAGly by glycyl-tRNA synthetase and provide facile access to positionally defined, isomeric glycl-tRNAGlys.     

Transfer RNA control of the activation of isomeric tRNATrp's.

Previous studies of the homologous aminoacylations of Escherichia coli and yeast tRNATrp's terminating in 2'- and 3'-deoxyadenosine established that E. coli tryptophanyl-tRNA synthetase activates its cognate tRNA preferentially on the 2' position, while the corresponding yeast enzyme utilizes the 3' position on its homologous substrate tRNA. As this seemed to be the only change in positional specificity during evolution, the heterologous activations were investigated in an effort to determine the basis for this change. Remarkably, E. coli tRNATrp terminating in 3'-deoxyadenosine was found to be the preferred substrate for both the E. coli and yeast activating enzymes, while the same tryptophanyl-tRNA synthetase preparations both activated the isomeric yeast tRNATrp's preferentially on the 3' position. Thus, the preferred position of activation was found to be specified by the tRNA rather than the activating enzyme and, additionally, to be due to some process not reflected in initial velocity measurements. The variable utilization of individual modified aminoacyl-tRNA's as substrates in an enzyme-catalyzed deacylation process appears to provide the most likely explanation for the experimental observations.     

Unilateral aminoacylation specificity between bovine mitochondria and eubacteria

The present study shows unilateral aminoacylation specificity between bovine mitochondria and eubacteria (Escherichia coli and Thermus thermophilus) in five amino acid-specific aminoacylation systems. Mitochondrial synthetases were capable of charging eubacterial tRNA as well as mitochondrial tRNA, whereas eubacterial synthetases did not efficiently charge mitochondrial tRNA. Mitochondrial phenylalanyl-, threonyl-, arginyl-, and lysyl-tRNA synthetases were shown to charge and discriminate cognate E. coli tRNA species from noncognate ones strictly, as did the corresponding E. coli synthetases. By contrast, mitochondrial seryl-tRNA synthetase not only charged cognate E. coli serine tRNA species but also extensively misacylated noncognate E. coli tRNA species. These results suggest a certain conservation of tRNA recognition mechanisms between the mitochondrial and E. coli aminoacyl-tRNA synthetases in that anticodon sequences are most likely to be recognized by the former four synthetases, but not sufficiently by the seryl-tRNA synthetase. The unilaterality in aminoacylation may imply that tRNA recognition mechanisms of the mitochondrial synthetases have evolved to be, to some extent, simpler than their eubacterial counterparts in response to simplifications in the species-number and the structural elements of animal mitochondrial tRNAs.     

Participation of X47-fluorescamine modified E. coli tRNAs in in vitro protein biosynthesis.

The reaction of fluorescamine with primary amino groups of tRNAs was investigated. The reagent was attached under mild conditions to the 3'-end of tRNAPhe-C-C-A(3'NH) from yeast and to the minor nucleoside x in E. coli tRNAArg, tRNALys, tRNAMet, tRNAIle and tRNAPhe. The primary aliphatic amino groups of these tRNAs react specifically so that the fluorescamine dye is not attached to the amino groups of the nucleobases. E. coli tRNA species modified on the minor nucleoside X47 can all be aminoacylated. An involvement of the minor modified nucleoside X47 in the tRNA: synthetase interaction is detected. Native tRNALys-C-C-A from E. coli can be phenylalanylated by phenylalanyl-tRNA synthetase from yeast, whereas this is not the case for fluorescamine treated tRNALys-C-C-A(XF47). Pre-tRNAPhe-C-C-A(XF47) forms a ternary complex with the elongation factor Tu:GTP from E. coli, binds enzymatically to the ribosomal A-site and is active in poly U dependent poly Phe synthesis. Fluorescamine-labelled E. coli tRNAs provide new substrates for the study of protein biosynthesis by spectroscopic methods.     

Mechanism of discrimination between cognate and non-cognate tRNAs by phenylalanyl-tRNA synthetase from yeast.

The interaction between phenylalanyl-tRNA synthetase from yeast and Escherichia coli and tRNAPhe (yeast), tRNASer (yeast), tRNA1Val (E. coli) has been investigated by ultracentrifugation analysis, fluorescence titrations and fast kinetic techniques. The fluorescence of the Y-base of tRNAPhe and the intrinsic fluorescence of the synthetases have been used as optical indicators. 1. Specific complexes between phenylalanyl-tRNA synthetase and tRNAPhe from yeast are formed in a two-step mechanism: a nearly diffusion-controlled recombination is followed by a fast conformational transition. Binding constants, rate constants and changes in the quantum yield of the Y-base fluorescence upon binding are given under a variety of conditions with respect to pH, added salt, concentration of Mg2+ ions and temperature. 2. Heterologous complexes between phenylalanyl-tRNA synthetase (E. coli) and tRNAPhe (yeast) are formed in a similar two-step mechanism as the specific complexes; the conformational transition, however, is slower by a factor 4-5. 3. Formation of non-specific complexes between phenylalanyl-tRNA synthetase (yeast) and tRNATyr (E. coli) proceeds in a one-step mechanism. Phenylalanyl-tRNA synthetase (yeast) binds either two molecules of tRNAPhe (yeast) or only one molecule of tRNATyr (E. coli); tRNA1Val (E. coli) or tRNASer (yeast) are also bound in a 1:1 stoichiometry. Binding constants for complexes of phenylalanyl-tRNA synthetase (yeast) and tRNATyr (E. coli) are determined under a variety of conditions. In contrast to specific complex formation, non-specific binding is disfavoured by the presence of Mg2+ ions, and is not affected by pH and the presence of pyrophosphate. The difference in the stabilities of specific and non-specific complexes can be varied by a factor of 2--100 depending on the ionic conditions. Discrimination of cognate and non-cognate tRNA by phenylalanyl-tRNA synthetase (yeast) is discussed in terms of the binding mechanism, the topology of the binding sites, the nature of interacting forces and the relation between specificity and ionic conditions.     

Aminoacylation of tRNAs as critical step of protein biosynthesis.

Isoleucyl-tRNA synthetases isolated from commercial baker's yeast and E coli were investigated for their sequences of substrate additions and product releases. The results show that aminoacylation of tRNA is catalyzed by these enzymes in different pathways, eg isoleucyl-tRNA synthetase from yeast can act with four different catalytic cycles. Amino acid specificities are gained by a four-step recognition process consisting of two initial binding and two proofreading steps. Isoleucyl-tRNA synthetase from yeast rejects noncognate amino acids with discrimination factors of D = 300-38000, isoleucyl-tRNA synthetase from E coli with factors of D = 600-68000. Differences in Gibbs free energies of binding between cognate and noncognate amino acids are related to different hydrophobic interaction energies and assumed conformational changes of the enzyme. A simple hypothetical model of the isoleucine binding site is postulated. Comparison of gene sequences of isoleucyl-tRNA synthetase from yeast and E coli exhibits only 27% homology. Both genes show the 'HIGH'- and 'KMSKS'-regions assigned to binding of ATP and tRNA. Deletion of 250 carboxyterminal amino acids from the yeast enzyme results in a fragment which is still active in the pyrophosphate exchange reaction but does not catalyze the aminoacylation reaction. The enzyme is unable to catalyze the latter reaction if more than 10 carboxyterminal residues are deleted.     

Non-essential role of lysine residues for the catalytic activities of aspartyl-tRNA synthetase and comparison with other aminoacyl-tRNA synthetases

Essential lysine residues were sought in the catalytic site of baker's yeast aspartyl-tRNA synthetase (an alpha 2 dimer of Mr 125,000) using affinity labeling methods and periodate-oxidized adenosine, ATP, and tRNA(Asp). It is shown that the number of periodate-oxidized derivatives which can be bound to the synthetase via Schiff's base formation with epsilon-NH2 groups of lysine residues exceeds the stoichiometry of specific substrate binding. Furthermore, it is found that the enzymatic activities are not completely abolished, even for high incorporation levels of the modified substrates. The tRNA(Asp) aminoacylation reaction is more sensitive to labeling than is the ATP-PPi exchange one; for enzyme preparations modified with oxidized adenosine or ATP this activity remains unaltered. These results demonstrate the absence of a specific lysine residue directly involved in the catalytic activities of yeast aspartyl-tRNA synthetase. Comparative labeling experiments with oxidized ATP were run with several other aminoacyl-tRNA synthetases. Residual ATP-PPi exchange and tRNA aminoacylation activities measured in each case on the modified synthetases reveal different behaviors of these enzymes when compared to that of aspartyl-tRNA synthetase. When tested under identical experimental conditions, pure isoleucyl-, methionyl-, threonyl- and valyl-tRNA synthetases from E. coli can be completely inactivated for their catalytic activities; for E. coli alanyl-tRNA synthetase only the tRNA charging activity is affected, whereas yeast valyl-tRNA synthetase is only partly inactivated. The structural significance of these experiments and the occurrence of essential lysine residues in aminoacyl-tRNA synthetases are discussed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence for a conserved relationship between an acceptor stem and a tRNA for aminoacylation.

The anticodon-independent aminoacylation of RNA hairpin helices that reconstruct tRNA acceptor stems has been demonstrated for at least 10 aminoacyl-tRNA synthetases. For Escherichia coli cysteine tRNA synthetase, the specificity of aminoacylation of the acceptor stem is determined by the U73 nucleotide adjacent to the amino acid attachment site. Because U73 is present in all known cysteine tRNAs, we investigated the ability of the E. coli cystein enzyme to aminoacylate a heterologous acceptor stem. We show here that a minihelixCys based on the acceptor-T psi C stem of yeast tRNACys is a substrate for the E. coli enzyme, and that aminoacylation of this minihelix is dependent on U73. Additionally, we identify two base pairs in the acceptor stem that quantitatively convert the E. coli acceptor stem to the yeast acceptor stem. The influence of U73 and these two base pairs is completely retained in the full-length tRNA. This suggests a conserved relationship between the acceptor stem alone and the acceptor stem in the context of a tRNA for aminoacylation with cysteine. However, the primary determinant in the species-specific aminoacylation of the E. coli and yeast cysteine tRNAs is a tertiary base pair at position 15:48 outside of the acceptor stem. Although E. coli tRNACys has an unusual G15:G48 tertiary base pair, yeast tRNACys has a more common G15:C48 that prevents efficient aminoacylation of yeast tRNACys by the E. coli enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of conformational features on the aminoacylation of tRNAs and consequences on the permutation of tRNA specificities.

The structure and function of in vitro transcribed tRNA(Asp) variants with inserted conformational features characteristic of yeast tRNA(Phe), such as the length of the variable region or the arrangement of the conserved residues in the D-loop, have been investigated. Although they exhibit significant conformational alterations as revealed by Pb2+ treatment, these variants are still efficiently aspartylated by yeast aspartyl-tRNA synthetase. Thus, this synthetase can accommodate a variety of tRNA conformers. In a second series of variants, the identity determinants of yeast tRNA(Phe) were transplanted into the previous structural variants of tRNA(Asp). The phenylalanine acceptance of these variants improves with increasing the number of structural characteristics of tRNA(Phe), suggesting that phenylalanyl-tRNA synthetase is sensitive to the conformational frame embedding the cognate identity nucleotides. These results contrast with the efficient transplantation of tRNA(Asp) identity elements into yeast tRNA(Phe). This indicates that synthetases respond differently to the detailed conformation of their tRNA substrates. Efficient aminoacylation is not only dependent on the presence of the set of identity nucleotides, but also on a precise conformation of the tRNA.     

Human cytosolic asparaginyl-tRNA synthetase: cDNA sequence, functional expression in Escherichia coli and characterization as human autoantigen.

The cDNA for human cytosolic asparaginyl-tRNA synthetase (hsAsnRSc) has been cloned and sequenced. The 1874 bp cDNA contains an open reading frame encoding 548 amino acids with a predicted M r of 62 938. The protein sequence has 58 and 53% identity with the homologous enzymes from Brugia malayi and Saccharomyces cerevisiae respectively. The human enzyme was expressed in Escherichia coli as a fusion protein with an N-terminal 4 kDa calmodulin-binding peptide. A bacterial extract containing the fusion protein catalyzed the aminoacylation reaction of S.cerevisiae tRNA with [14C]asparagine at a 20-fold efficiency level above the control value confirming that this cDNA encodes a human AsnRS. The affinity chromatography purified fusion protein efficiently aminoacylated unfractionated calf liver and yeast tRNA but not E.coli tRNA, suggesting that the recombinant protein is the cytosolic AsnRS. Several human anti-synthetase sera were tested for their ability to neutralize hsAsnRSc activity. A human autoimmune serum (anti-KS) neutralized hsAsnRSc activity and this reaction was confirmed by western blot analysis. The human asparaginyl-tRNA synthetase appears to be like the alanyl- and histidyl-tRNA synthetases another example of a human Class II aminoacyl-tRNA synthetase involved in autoimmune reactions.     

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.     

Both positional isomers of aminoacyl-tRNA's are bound by elongation factor Tu.

Six purified Escherichia coli and yeast tRNA's were converted to positionally defined tRNA's terminating in 2'- and 3'-deoxyadenosine; the modified (amino-acyl) tRNA's were compared for their abilities to bind to elongation factor Tu (EF-Tu) in the presence both of GTP and guanylylimidodiphosphate (GMP-P(NH)P). Formation of aminoacyl-tRNA . EF-Tu . guanine nucleotide ternary complexes was monitored by gel filtration on Sephadex G-100 and Ultrogel ACA 44 columns and also by measurement of the ability of the factor to diminish the rate of chemical hydrolysis of the aminoacyl-tRNA's. The apparent positional specificity of the factor was found to be affected substantially both by the choice of guanine nucleotide and gel filtration resin utilized, but not in any systematic fashion. Likewise, assay of ternary complex formation by diminution of the rate of chemical deacylation failed to reveal any consistent positional preference from one isoacceptor to another. It is worthy of note that each modified aminoacyl-tRNA tested did form a ternary complex with EF-Tu under each of the experimental conditions used for assay, but that in each case the difference in affinity of the factor for isomeric aminoacyl-tRNA's was less than that between either of the modified aminoacyl-tRNA's and the corresponding unmodified species. On the basis of the experiments performed, we conclude that (i) EF-Tu has remarkable conformation flexibility, possibly reflecting its physiological role in recognizing 20 tRNA isoacceptors and (ii) the factor has no obvious preference for a single positional isomer of aminoacyl-tRNA and it is not clear that any preference that might exist could be established convincingly using tRNA's terminating in 2'- and 3'-deoxyadenosine.     

Competition of aminoacyl-tRNA synthetases for tRNA ensures the accuracy of aminoacylation.

The accuracy of protein biosynthesis rests on the high fidelity with which aminoacyl-tRNA synthetases discriminate between tRNAs. Correct aminoacylation depends not only on identity elements (nucleotides in certain positions) in tRNA (1), but also on competition between different synthetases for a given tRNA (2). Here we describe in vivo and in vitro experiments which demonstrate how variations in the levels of synthetases and tRNA affect the accuracy of aminoacylation. We show in vivo that concurrent overexpression of Escherichia coli tyrosyl-tRNA synthetase abolishes misacylation of supF tRNA(Tyr) with glutamine in vivo by overproduced glutaminyl-tRNA synthetase. In an in vitro competition assay, we have confirmed that the overproduction mischarging phenomenon observed in vivo is due to competition between the synthetases at the level of aminoacylation. Likewise, we have been able to examine the role competition plays in the identity of a non-suppressor tRNA of ambiguous identity, tRNA(Glu). Finally, with this assay, we show that the identity of a tRNA and the accuracy with which it is recognized depend on the relative affinities of the synthetases for the tRNA. The in vitro competition assay represents a general method of obtaining qualitative information on tRNA identity in a competitive environment (usually only found in vivo) during a defined step in protein biosynthesis, aminoacylation. In addition, we show that the discriminator base (position 73) and the first base of the anticodon are important for recognition by E. coli tyrosyl-tRNA synthetase.     

Pre-transfer editing by class II prolyl-tRNA synthetase: role of aminoacylation active site in "selective release" of noncognate amino acids

Aminoacyl-tRNA synthetases catalyze the attachment of cognate amino acids to specific tRNA molecules. To prevent potential errors in protein synthesis caused by misactivation of noncognate amino acids, some synthetases have evolved editing mechanisms to hydrolyze misactivated amino acids (pre-transfer editing) or misacylated tRNAs (post-transfer editing). In the case of post-transfer editing, synthetases employ a separate editing domain that is distinct from the site of amino acid activation, and the mechanism is believed to involve shuttling of the flexible CCA-3' end of the tRNA from the synthetic active site to the site of hydrolysis. The mechanism of pre-transfer editing is less well understood, and in most cases, the exact site of pre-transfer editing has not been conclusively identified. Here, we probe the pre-transfer editing activity of class II prolyl-tRNA synthetases from five species representing all three kingdoms of life. To locate the site of pre-transfer editing, truncation mutants were constructed by deleting the insertion domain characteristic of bacterial prolyl-tRNA synthetase species, which is the site of post-transfer editing, or the N- or C-terminal extension domains of eukaryotic and archaeal enzymes. In addition, the pre-transfer editing mechanism of Escherichia coli prolyl-tRNA synthetase was probed in detail. These studies show that a separate editing domain is not required for pre-transfer editing by prolyl-tRNA synthetase. The aminoacylation active site plays a significant role in preserving the fidelity of translation by acting as a filter that selectively releases non-cognate adenylates into solution, while protecting the cognate adenylate from hydrolysis.     

Domain-domain communication for tRNA aminoacylation: the importance of covalent connectivity

Aminoacyl-tRNA synthetases form complexes with tRNA to catalyze transfer of activated amino acids to the 3' end of tRNA. The tRNA synthetase complexes are roughly divided into the activation and tRNA-binding domains of synthetases, which interact with the acceptor and anticodon ends of tRNAs, respectively. Efficient aminoacylation of tRNA by Escherichia coli cysteinyl-tRNA synthetase (CysRS) requires both domains, although the pathways for the long-range domain-domain communication are not well understood. Previous studies show that dissection of tRNA(Cys) into acceptor and anticodon helices seriously reduces the efficiency of aminoacylation, suggesting that communication requires covalent continuity of the tRNA backbone. Here we tested if communication requires the continuity of the synthetase backbone. Two N-terminal fragments and one C-terminal fragment of E. coli CysRS were generated. While the N-terminal fragments were active in adenylate synthesis, they were severely defective in the catalytic efficiency and specificity of tRNA aminoacylation. Conversely, although the C-terminal fragment was not catalytically active, it was able to bind and discriminate tRNA. However, addition of the C-terminal fragment to an N-terminal fragment in trans did not improve the aminoacylation efficiency of the N-terminal fragment to the level of the full-length enzyme. These results emphasize the importance of covalent continuity of both CysRS and tRNA(Cys) for efficient tRNA aminoacylation, and highlight the energetic costs of constraining the tRNA synthetase complex for domain-domain communication. Importantly, this study also provides new insights into the existence of several natural "split" synthetases that are now identified from genomic sequencing projects.