Modulation of replication, aminoacylation and adenylation in vitro and infectivity in vivo of BMV RNAs containing deletions within the multifunctional 3'' end.

The genome of brome mosaic virus (BMV) is comprised of three (+) strand RNAs, each containing a similar, highly structured, 200 base long sequence at its 3' end. A 134 base subset of this sequence contains signals directing interaction of the viral RNA with BMV RNA replicase, ATP,CTP:tRNA nucleotidyl transferase and aminoacyl tRNA synthetase. A series of mutants containing deletions within this region, previously constructed and tested in vitro for the effect on replication and aminoacylation activities, has now been assayed in vitro for adenylation function and in vivo for ability to replicate in isolated protoplasts and whole plants. These tests indicate that features of viral RNA recognized by BMV replicase overlap those directing adenylation, but are distinct from those directing aminoacylation. Consequently, the lethality of a deletion preferentially inhibiting aminoacylation suggests that this function may have an essential role contributing to viral replication in vivo. An RNA3 mutant bearing a 20-base deletion yielding normal levels of aminoacylation and enhanced levels of replicase template activity and adenylation in vitro was able to replicate in protoplasts and plants; however, its accumulation in protoplasts was reduced relative to wild-type. This suggests that additional functions affecting the replication and accumulation of viral RNA reside in the conserved 3' sequence.     

Isoleucyl-tRNA synthetase from Escherichia coli MRE 600: discrimination between isoleucine and valine with modulated accuracy

Discrimination between isoleucine and valine is achieved with different accuracies by isoleucyl-tRNA synthetase from E. coli MRE 600. The recognition process consists of two initial discrimination steps and a pretransfer and a posttransfer proofreading event. The overall discrimination factors D were determined from kcat and Km values observed in aminoacylation of tRNA(Ile)-C-C-A with isoleucine and valine. From aminoacylation of the modified tRNA species tRNA(Ile)-C-C-A(3'NH2) initial discrimination factors I1 and pretransfer proofreading factors II1 were calculated. Factors I1 were computed from ATP consumption and D1, the overall discrimination in aminoacylation of the modified tRNA; factors II1 were calculated as quotient of AMP formation rates. Initial discrimination factors I2 and posttransfer proofreading factors II2 were determined from AMP formation rates observed in aminoacylation of tRNA(Ile)-C-C-A. The observed overall discrimination varies up to a factor of about four according to conditions. Under standard assay conditions 72,000, under optimal conditions 144,000 correct aminoacyl-tRNAs are produced per one error while 1.1 or 1.7 ATPs are consumed. A comparison with isoleucyl-tRNA synthetase from yeast shows that both enzymes act principally with the same recognition mechanism, but the enzyme from E. coli MRE 600 exhibits higher specificity and lower energy dissipation and does not show such high variation of accuracy as observed with the enzyme from yeast.     

Isoleucyl-tRNA synthetase from Baker's yeast. Catalytic mechanism, 2',3'-specificity and fidelity in aminoacylation of tRNAIle with isoleucine and valine investigated with initial-rate kinetics using analogs of tRNA, ATP and amino acids

The aminoacylation of three modified tRNAIle species with isoleucine and with valine by isoleucyl-tRNA synthetase has been investigated by initial rate kinetics. For aminoacylation of tRNAIle-C-C-3'dA with isoleucine, a bi-bi uni-uni ping-pong mechanism has been found by bisubstrate kinetics and inhibition by products and by 3'dATP; for aminoacylation with valine a bi-uni uni-bi ping-pong mechanism. For isoleucylation of tRNAIle-C-C-A(3'NH2) bisubstrate kinetics, inhibition by products and by isoleucinol show a random uni-bi uni-uni-uni ping-pong mechanism; for valylation of this tRNA a bi-bi uni-uni ping-pong mechanism is observed by bisubstrate kinetics and product inhibition. tRNAIle-C-C-2'dA was aminoacylated under modified conditions with isoleucine in a bi-bi uni-uni ping-pong mechanism with a rapid equilibrium segment as observed by bisubstrate kinetics, inhibition by AMP, by P[NH]P as product analog and by isoleucinol. Aminoacylation with valine is achieved in a rapid-equilibrium sequential random AB, ordered C mechanism indicated by bisubstrate kinetics and inhibition by 3'dATP and valinol. All six reactions exhibit orders of substrate addition and product release which are different from those observed in aminoacylation of the natural tRNAIle-C-C-A. The Km values of the three substrates and the kcat values of the six reactions are given. For aminoacylation at the terminal 2'OH group of the tRNA differences of 13.38 and 13.17 kJ in binding energies between valine and isoleucine have been calculated which result in discrimination factors of 181 and 167. For aminoacylation at the terminal 3'-OH group a difference of only 4.43 kJ and a low discrimination factor of only 6 is observed. Thus maximal discrimination between the cognate and the noncognate amino acid is only achieved in aminoacylation at the 2'-OH group and conclusions drawn from experiments with modified tRNAs concerning 2',3'-specificity have led to correct results in spite of different catalytic cycles in aminoacylation of the natural and the modified tRNAs. The stability of Ile-tRNAIle-C-C-2'dA and Val-tRNAIle-C-C-2'dA, the lesser stability of Val-tRNAVal-C-C-2'dA and the instability of Thr-tRNAVal-C-C-2'dA are consistent with postulations for a 'pre-transfer' proofreading step for isoleucyl-tRNA synthetase and a 'post-transfer' hydrolytic editing step for valyl-tRNA synthetase at the terminal 3'OH group of the tRNA.     

Functionally impaired tRNA from ethionine treated rats as detected in injected Xenopus oocytes.

Treatment of rats with ethionine was found to cause severe impairment in the aminoacylation capacity of tRNA. This effect was only observed when assayed in injected oocytes, while invitro assays of aminoacylation failed to detect differences between normal tRNA and tRNA from ethionine treated animals. The effect of ethionine on the tRNA population was not uniform and differed for various amino acid specific tRNAs. Thus liver tRNA from ethionine treated rats showed a decreased capacity for phenylalanine aminoacylation, while no change was found in the case of leucine. On the other hand, the level of histidine aminoacylation was higher for tRNA from ethionine treated animals. An even more complex response was observed with methionine aminoacylation where tRNA from ethionine treated animals showed an initially faster rate than control tRNA. With more prolonged incubation periods, the methionyl-tRNA from ethionine treated animals was deacylated at an accelerated rate while the level of normal methionyl-tRNA remained almost constant.In addition to the aminoacylation reaction, the participation of aminoacyl-tRNA in protein synthesis was severely impaired. In this case, both the injected oocyte system and the cell-free wheat germ assay revealed these differences which were manifested with various mRNA and viral RNA preparations.     

Recognition of tRNA backbone for aminoacylation with cysteine: evolution from Escherichia coli to human

The underlying basis of the genetic code is specific aminoacylation of tRNAs by aminoacyl-tRNA synthetases. Although the code is conserved, bases in tRNA that establish aminoacylation are not necessarily conserved. Even when the bases are conserved, positions of backbone groups that contribute to aminoacylation may vary. We show here that, although the Escherichia coli and human cysteinyl-tRNA synthetases both recognize the same bases (U73 and the GCA anticodon) of tRNA for aminoacylation, they have different emphasis on the tRNA backbone. The E. coli enzyme recognizes two clusters of phosphate groups. One is at A36 in the anticodon and the other is in the core of the tRNA structure and includes phosphate groups at positions 9, 12, 14, and 60. Metal-ion rescue experiments show that those at positions 9, 12, and 60 are involved with binding divalent metal ions that are important for aminoacylation. The E. coli enzyme also recognizes 2'-hydroxyl groups within the same two clusters: at positions 33, 35, and 36 in the anticodon loop, and at positions 49, 55, and 61 in the core. The human enzyme, by contrast, recognizes few phosphate or 2'-hydroxy groups for aminoacylation. The evolution from the backbone-dependent recognition by the E. coli enzyme to the backbone-independent recognition by the human enzyme demonstrates a previously unrecognized shift that nonetheless has preserved the specificity for aminoacylation with cysteine.     

A unique insert of leucyl-tRNA synthetase is required for aminoacylation and not amino acid editing

Leucyl-tRNA synthetase (LeuRS) is a class I enzyme, which houses its aminoacylation active site in a canonical core that is defined by a Rossmann nucleotide binding fold. In addition, many LeuRSs bear a unique polypeptide insert comprised of about 50 amino acids located just upstream of the conserved KMSKS sequence. The role of this leucine-specific domain (LS-domain) remains undefined. We hypothesized that this domain may be important for substrate recognition in aminoacylation and/or amino acid editing. We carried out a series of deletion mutations and chimeric swaps within the leucine-specific domain of Escherichia coli. Our results support that the leucine-specific domain is critical for aminoacylation but not required for editing activity. Kinetic analysis determined that deletion of the LS-domain primarily impacts kcat. Because of its proximity to the aminoacylation active site, we propose that this domain interacts with the tRNA during amino acid activation and/or tRNA aminoacylation. Although the leucine-specific domain does not appear to be important to the editing complex, it remains possible that it aids the dynamic translocation process that moves tRNA from the aminoacylation to the editing complex.     

Subunit structure and tRNA-binding properties of Bombyx mori Glycyl-tRNA synthetase

Large amounts of glycyl-tRNA synthetase were purified from the posterior silk glands of Bombyx mori. The synthetase was estimated to be a dimer with a molecular weight of 180,000. When the enzyme solution was diluted, the dimer dissociated into monomers which were inactive in tRNA aminoacylation. The aminoacylation was investigated with two isoaccepting tRNAsGly isolated from the posterior silk glands. Transfer RNA1Gly was aminoacylated 2-fold faster than tRNA2Gly. Transfer RNA-binding experiments revealed that tRNA1Gly binds with the enzyme in a molar ratio of 2:1, whereas tRNA2Gly formed a 1:1 complex with the enzyme. Based on these experimental results, we proposed that the Bombyx mori glycyl-tRNA synthetase has two active sites for tRNA aminoacylation and that the number of tRNA molecules bound on the synthetase closely correlates with the velocity of aminoacylation.     

Arginyl-tRNA synthetase from yeast. Discrimination between 20 amino acids in aminoacylation of tRNA(Arg)-C-C-A and tRNA(Arg)-C-C-A(3'NH2)

For discrimination between arginine and 19 other amino acids in aminoacylation of tRNA(Arg)-C-C-A by arginyl-tRNA synthetase from baker's yeast, discrimination factors (D) have been determined from kcat and Km values. The lowest values were found for Trp, Cys, Lys (D = 800-8500), showing that arginine is 800-8500 times more often incorporated into tRNA(Arg)-C-C-A than noncognate acids at the same amino acid concentrations. The other noncognate amino acids exhibit D values between 10,000 and 60,000. In aminoacylation of tRNA(Arg)-C-C-A(3'NH2) discrimination factors D1 are in the range 10-600. From these values and AMP formation stoichiometry, pretransfer proof-reading factors II1 were determined; from D values and AMP stoichiometry in aminoacylation of tRNA(Arg)-C-C-A, posttransfer proof-reading factors II2 could be calculated, II1 values between 2 and 120 show that pretransfer proof-reading is the main correction step, posttransfer proof-reading (II2 approximately 1-10) plays a marginal role. Initial discrimination factors due to different Gibbs free energies of binding between arginine and the noncognate amino acids were calculated from discrimination and proof-reading factors. According to a two-step binding process, two factors (I1 and I2) were determined. They can be related to hydrophobic interaction forces and hydrogen bonds that are especially formed by the arginine side chain. A hypothetical 'stopper' model of the amino acid recognition site is discussed.     

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.     

Tyrosyl-tRNA synthetase from baker's yeast. Order of substrate addition, discrimination of 20 amino acids in aminoacylation of tRNATyr-C-C-A and tRNATyr-C-C-A(3'NH2)

The order of substrate addition to tyrosyl-tRNA synthetase from baker's yeast was investigated by bisubstrate kinetics, product inhibition and inhibition by dead-end inhibitors. The kinetic patterns are consistent with a random bi-uni uni-bi ping-pong mechanism. Substrate specificity with regard to ATP analogs shows that the hydroxyl groups of the ribose moiety and the amino group in position 6 of the base are essential for recognition of ATP as substrate. Specificity with regard to amino acids is characterized by discrimination factors D which are calculated from kcat and Km values obtained in aminoacylation of tRNATyr-C-C-A. The lowest values are observed for Cys, Phe, Trp (D = 28,000-40,000), showing that, at the same amino acid concentrations, tyrosine is 28,000-40,000 times more often attached to tRNATyr-C-C-A than the noncognate amino acids. With Gly, Ala and Ser no misacylation could be detected (D greater than 500,000); D values of the other amino acids are in the range of 100,000-500,000. Lower specificity is observed in aminoacylation of the modified substrate tRNATyr-C-C-A(3'NH2) (D1 = 500-55,000). From kinetic constants and AMP-formation stoichiometry observed in aminoacylation of this tRNA species, as well as in acylating tRNATyr-C-C-A hydrolytic proof-reading factors could be calculated for a pretransfer (II 1) and a post-transfer (II 2) proof-reading step. The observed values of II 1 = 12-280 show that pretransfer proof-reading is the main correction step whereas post-transfer proof-reading is marginal for most amino acids (II 2 = 1-2). Initial discrimination factors caused by differences in Gibbs free energies of binding between tyrosine and noncognate amino acids are calculated from discrimination and proof-reading factors. Assuming a two-step binding process, two factors (I1 and I2) are determined which can be related to hydrophobic interaction forces. The tyrosine side chain is bound by hydrophobic forces and hydrogen bonds formed by its hydroxyl group. A hypothetical model of the amino acid binding site is discussed and compared with results of X-ray analysis of the enzyme from Bacillus stearothermophilus.     

Relationship of the CCA sequence of tRNA with the early evolutional aspect of aminoacyl-tRNA synthetases.

The CCA sequence is common to the 3'-ends of all tRNAs. We investigated the requirement of the CCA sequence in aminoacylation with the cognate aminoacyl-tRNA synthetases (aaRSs) and several interesting conclusions could be drawn. In tRNAs belonging to the class I aaRSs, decreased aminoacylation activities resulted from the substitution of A76 with a pyrimidine, whereas in tRNAs belonging to the class II aaRSs, decreased aminoacylation activities resulted from the substitution with guanine. The results suggest that aminoacylation of proto-tRNA might have started through the direct hydrophobic (or stacking) interaction between the large, hydrophobic amino acid residue (now utilizing a class I aaRS) of aminoacyl-AMP and the 3'-terminal adenine. The shorter distance between the adenine and the 2'-OH position than the 3'-OH position, and the bulkiness and hydrophobicity of amino acids may be important reasons why class I aaRSs select the 2'-OH position in aminoacylation. Molecular mechanics-based conformation modeling also indicated that the resulting positioning of the adenine and the amino acid residue of 2'-aminoacyl-adenosine for large amino acid is in the vicinity. In contrast, in the case of small amino acids (with class II aaRSs) which would not be able to use the hydrophobic interaction, a protein enzyme might have participated in the aminoacylation reaction from an early stage. The active-site folds of aaRSs belonging to each class reflect the history of evolution: typical nucleotide-binding fold (Rossman fold) in the case of class I aaRSs, and primitive fold which is found also among the family of nonribosomal peptide synthetases in the case of class II aaRSs.     

The infectivities of turnip yellow mosaic virus genomes with altered tRNA mimicry are not dependent on compensating mutations in the viral replication protein

Five highly infectious turnip yellow mosaic virus (TYMV) genomes with sequence changes in their 3'-terminal regions that result in altered aminoacylation and eEF1A binding have been studied. These genomes were derived from cloned parental RNAs of low infectivity by sequential passaging in plants. Three of these genomes that are incapable of aminoacylation have been reported previously (J. B. Goodwin, J. M. Skuzeski, and T. W. Dreher, Virology 230:113-124, 1997). We now demonstrate by subcloning the 3' untranslated regions into wild-type TYMV RNA that the high infectivities and replication rates of these genomes compared to their progenitors are mostly due to a small number of mutations acquired in the 3' tRNA-like structure during passaging. Mutations in other parts of the genome, including the replication protein coding region, are not required for high infectivity but probably do play a role in optimizing viral amplification and spread in plants. Two other TYMV RNA variants of suboptimal infectivities, one that accepts methionine instead of the usual valine and one that interacts less tightly with eEF1A, were sequentially passaged to produce highly infectious genomes. The improved infectivities of these RNAs were not associated with increased replication in protoplasts, and no mutations were acquired in their 3' tRNA-like structures. Complete sequencing of one genome identified two mutations that result in amino acid changes in the movement protein gene, suggesting that improved infectivity may be a function of improved viral dissemination in plants. Our results show that the wild-type TYMV replication proteins are able to amplify genomes with 3' termini of variable sequence and tRNA mimicry. These and previous results have led to a model in which the binding of eEF1A to the 3' end to antagonize minus-strand initiation is a major role of the tRNA-like structure.     

Functional group recognition at the aminoacylation and editing sites of E. coli valyl-tRNA synthetase

To correct misactivation and misacylation errors, Escherichia coli valyl-tRNA synthetase (ValRS) catalyzes a tRNA(Val)-dependent editing reaction at a site distinct from its aminoacylation site. Here we examined the effects of replacing the conserved 3'-adenosine of tRNA(Val) with nucleoside analogs, to identify structural elements of the 3'-terminal nucleoside necessary for tRNA function at the aminoacylation and editing sites of ValRS. The results show that the exocyclic amino group (N6) is not essential: purine riboside-substituted tRNA(Val) is active in aminoacylation and in stimulating editing. Presence of an O6 substituent (guanosine, inosine, xanthosine) interferes with aminoacylation as well as posttransfer and total editing (pre- plus posttransfer editing). Because ValRS does not recognize substituents at the 6-position, these results suggest that an unprotonated N1, capable of acting as an H-bond acceptor, is an essential determinant for both the aminoacylation and editing reactions. Substituents at the 2-position of the purine ring, either a 2-amino group (2-aminopurine, 2,6-diaminopurine, guanosine, and 7-deazaguanosine) or a 2-keto group (xanthosine, isoguanosine), strongly inhibit both aminoacylation and editing. Although aminoacylation by ValRS is at the 2'-OH, substitution of the 3'-terminal adenosine of tRNA(Val) with 3'-deoxyadenosine reduces the efficiency of valine acceptance and of posttransfer editing, demonstrating that the 3'-terminal hydroxyl group contributes to tRNA recognition at both the aminoacylation and editing sites. Our results show a strong correlation between the amino acid accepting activity of tRNA and its ability to stimulate editing, suggesting misacylated tRNA is a transient intermediate in the editing reaction, and editing by ValRS requires a posttransfer step.     

Comparison of porcine liver tRNA preparations: Purification of tRNA and its separation from RNA-peptidyl complexes

Six fractions of soluble RNA were obtained from phenol extracts of porcine liver and were tested for their acceptance of 14 amino acids under aminoacylation conditions and for their effects on the aminoacylation of tRNA. Two of the fractions contained appreciable amounts of tRNA, and three of the fractions affected the aminoacylation of tRNA. Based on these observations a revised method of tRNA preparation was developed that includes essentially all the tRNA in one fraction but that excludes the RNA-peptidyl complexes. The revised method is rapid and convenient and provides better quality tRNA than three alternate methods to which it is compared.     

Transfer RNA determinants for translational editing by Escherichia coli valyl-tRNA synthetase

Valyl-tRNA synthetase (ValRS) has difficulty differentiating valine from structurally similar non-cognate amino acids, most prominently threonine. To minimize errors in aminoacylation and translation the enzyme catalyzes a proofreading (editing) reaction that is dependent on the presence of cognate tRNA^Val. Editing occurs at a site functionally distinct from the aminoacylation site of ValRS and previous results have shown that the 3′-terminus of tRNA^Val is recognized differently at the two sites. Here, we extend these studies by comparing the contribution of aminoacylation identity determinants to productive recognition of tRNA^Val at the aminoacylation and editing sites, and by probing tRNA^Val for editing determinants that are distinct from those required for aminoacylation. Mutational analysis of Escherichia coli tRNA^Val and identity switch experiments with non-cognate tRNAs reveal a direct relationship between the ability of a tRNA to be aminoacylated and its ability to stimulate the editing activity of ValRS. This suggests that at least a majority of editing by the enzyme entails prior charging of tRNA and that misacylated tRNA is a transient intermediate in the editing reaction.     

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.     

Biological activity of tRNA in rat liver during cycloheximide-blocked translation

The aminoacylation of tRNA was investigated with respect to protein synthesis in the rat liver. No correlation was found between the 85-90% inhibition of protein synthesis 2 h after cycloheximide injection and aminoacylation level of some tRNAs both in vivo and in vitro. A decrease in aminoacylation (28%) was established only for lysine. During the recovery phase of protein synthesis 12 and 24 h after cycloheximide treatment the aminoacylation maximal level of mixture with 14C amino acids, 14C leucine, 14C glutamic acid was unchanged.     

RNA minihelices and the decoding of genetic information

The rules of the genetic code are determined by the specific aminoacylation of transfer RNAs by aminoacyl transfer RNA synthetase. A straightforward analysis shows that a system of synthetase-tRNA interactions that relies on anticodons for specificity could, in principle, enable most synthetases to distinguish their cognate tRNA isoacceptors from all others. Although the anticodons of some tRNAs are recognition sites for the cognate aminoacyl tRNA synthetases, for other synthetases the anticodon is dispensable for specific aminoacylation. In particular, alanine and histidine tRNA synthetases aminoacylate small RNA minihelices that reconstruct the part of their cognate tRNAs that is proximate to the amino acid attachment site. Helices with as few as six base pairs can be efficiently aminoacylated. The specificity of aminoacylation is determined by a few nucleotides and can be converted from one amino acid to another by the change of only a few nucleotides. These findings suggest that, for a subgroup of the synthetases, there is a distinct code in the acceptor helix of transfer RNAs that determines aminoacylation specificity.     

Aminoacylation of tRNA Trp from beef liver, yeast and E. coli by beef pancrease tryptophan-tRNA ligase. Stoichiometry of tRNATrp binding.

The Michaelis constants and the maximum velocities in the aminoacylation reaction of tRNATrp from beef liver, yeast and E. coli by pure beef pancreas tryptophan-tRNA ligase show that this mammalian enzyme recognizes and charges the two eucaryotic tRNAs with the same efficiency. The rate of aminoacylation of the procaryotic tRNATrp by the enzyme is three orders of magnitude lower. The pH optimum of aminoacylation is 8 for both eucaryotic tRNAs. The optimum magnesium concentration is different. The rate is maximum when magnesium concentration is stoichiometric to ATP concentration for tRNATrp from beef liver and 10 mM above ATP concentration for tRNATrp from yeast. The number of binding sites on the enzyme for the two eucaryotic tRNAs has been measured by equilibrium filtration on Sephadex G-100 and found equal to two.     

Purification of isoleucyl-tRNA synthetase from Methanobacterium thermoautotrophicum by pseudomonic acid affinity chromatography

The isoleucyl-tRNA synthetase of the archaebacterium Methanobacterium thermoautotrophicum was purified 1500-fold to electrophoretic homogeneity by a procedure based on affinity chromatography on Sepharose-bound pseudomonic acid, a strong competitive inhibitor of this enzyme. The purified enzyme is a monomer with a molecular mass of 120 kDa. In this respect and in its Km values for the PPi-ATP exchange, and aminoacylation reactions, it resembles the isoleucyl-tRNA synthetases from eubacterial and eukaryotic sources. Its aminoacylation activity is optimal at pH 8.0 and at 55 degrees C. Pseudomonic acid is a strong competitive inhibitor of the aminoacylation reaction with respect to both L-isoleucine (KiIle 10 nM) and ATP (KiATP 20 nM).