Interaction between human tRNA synthetases involves repeated sequence elements

Aminoacyl-tRNA synthetases (tRNA synthetases) of higher eukaryotes form a multiprotein complex. Sequence elements that are responsible for the protein assembly were searched by using a yeast two-hybrid system. Human cytoplasmic isoleucyl-tRNA synthetase is a component of the multi-tRNA synthetase complex and it contains a unique C-terminal appendix. This part of the protein was used as bait to identify an interacting protein from a HeLa cDNA library. The selected sequence represented the internal 317 amino acids of human bifunctional (glutamyl- and prolyl-) tRNA synthetase, which is also known to be a component of the complex. Both the C-terminal appendix of the isoleucyl-tRNA synthetase and the internal region of bifunctional tRNA synthetase comprise repeating sequence units, two repeats of about 90 amino acids, and three repeats of 57 amino acids, respectively. Each repeated motif of the two proteins was responsible for the interaction, but the stronger interaction was shown by the native structures containing multiple motifs. Interestingly, the N-terminal extension of human glycyl-tRNA synthetase containing a single motif homologous to those in the bifunctional tRNA synthetase also interacted with the C-terminal motif of the isoleucyl-tRNA synthetase although the enzyme is not a component of the complex. The data indicate that the multiplicity of the binding motif in the tRNA synthetases is necessary for enhancing the interaction strength and may be one of the determining factors for the tRNA synthetases to be involved in the formation of the multi-tRNA synthetase complex.

Differences in the magnesium dependences of the class I and class II aminoacyl-tRNA synthetases from Escherichia coli

The magnesium dependences of the ATP/PPi exchange and tRNA aminoacylation of reactions were measured for six aminoacyl-tRNA synthetases (isoleucyl-, tyrosyl- and arginyl-tRNA synthetases from class I, and histidyl-, lysyl- and phenylalanyl-tRNA synthetases from class II). The measured values were subjected to best-fit analyses using sum square error calculations between the data and the calculated curves in order to find the mode of participation of the Mg2+ and to optimize the sets of the kinetic constants. The following four dependences were observed: the class II synthetases require three Mg2+ for the activation reaction (including the one in MgATP), but the class I synthetases require only one Mg2+ (in MgATP); in class II synthetases both MgPPi and Mg2PPi participate in the pyrophosphorolysis of the aminoacyl adenylate. Arginyl-tRNA synthetase from class I also shows a better fit if also Mg2PPi reacts, but in the isoleucyl- and tyrosyl-tRNA synthetases only MgPPi but not Mg2PPi is used in the pyrophosphorolysis. Different synthetases have different requirements for the tRNA-bound Mg2+ and spermidine, independent of the enzyme class. 1-4 Mg2+ or spermidines are required in the best fit models. At the end of the reaction in all the synthetases analysed the dissociation of Mg2+ from the product aminoacyl-tRNA essentially enhances the subsequent dissociation of the aminoacyl-tRNA from the enzyme. The binding of ATP to the E. aminoacyl-tRNA complex also speeds up the dissociation of the aminoacyl-tRNA from most of these enzymes.

A eubacterial Mycobacterium tuberculosis tRNA synthetase is eukaryote-like and resistant to a eubacterial-specific antisynthetase drug

We report here the cloning and primary structure of Mycobacterium tuberculosis isoleucyl-tRNA synthetase. The predicted 1035-amino acid protein is significantly more similar in sequence to eukaryote cytoplasmic than to other eubacterial isoleucyl-tRNA synthetases. This similarity correlates with the enzyme being resistant to pseudomonic acid A, a potent inhibitor of Escherichia coli and other eubacterial isoleucyl-tRNA synthetases, but not of eukaryote cytoplasmic enzymes. Consistent with its eukaryote-like features, and unlike E. coli isoleucyl-tRNA synthetase, the M. tuberculosis enzyme charged yeast isoleucine tRNA. In spite of these eukaryote-like features, M. tuberculosis isoleucyl-tRNA synthetase exhibited highly specific cross-species aminoacylation, as demonstrated by its ability to complement isoleucyl-tRNA synthetase-deficient mutants of E. coli. When introduced into a pseudomonic acid-sensitive wild-type strain of E. coli, the M. tuberculosis enzyme conferred trans-dominant resistance to the drug. The results demonstrate that the sequence of a tRNA synthetase could have predictive value with respect to the interaction of that synthetase with a specific inhibitor. The results also demonstrate that mobilization of a pathogen's gene for a drug-resistant protein target can spread resistance to other, normally drug-sensitive pathogens infecting the same host.

Proofreading in trans by an aminoacyl-tRNA synthetase: a model for single site editing by isoleucyl-tRNA synthetase

Editing of errors in amino acid selection by an aminoacyl-tRNA synthetase prevents attachment of incorrect amino acids to tRNA, thereby greatly enhancing accuracy of translation of the genetic code. Editing of the non-protein amino acid homocysteine, a frequent type of an error-correcting process, involves reaction of the side chain sulfhydryl group of homocysteine with its activated carboxyl group forming a cyclic thioester, homocysteine thiolactone. Here, it is shown that isoleucyl-tRNA synthetase (IleRS), which occasionally misactivates homocysteine in vitro and in vivo, catalyzes reactions of activated isoleucine with organic thiols (analogues of the side chain of homocysteine). That these enzymatic reactions occur between Ile-tRNAIle or Ile-AMP (bound in the synthetic sub-site) and a thiol (an analogue of the side chain of homocysteine, bound in the editing sub-site), indicates that the two sub-sites are physically close on the surface of IleRS, forming a single synthetic/editing active site of the enzyme. Although IleRS.Val-AMP undergoes thiolysis as efficiently as do IleRS.Ile-AMP and IleRS.Ile-tRNAIle, IleRS.Val-tRNAIle does not react with thiols. These and other data suggest that the mischarged valine residue in IleRS.Val-tRNAIle is, most likely, positioned off the enzyme.

Protein synthesis editing by a DNA aptamer

Potential errors in decoding genetic information are corrected by tRNA-dependent amino acid recognition processes manifested through editing reactions. One example is the rejection of difficult-to-discriminate misactivated amino acids by tRNA synthetases through hydrolytic reactions. Although several crystal structures of tRNA synthetases and synthetase-tRNA complexes exist, none of them have provided insight into the editing reactions. Other work suggested that editing required active amino acid acceptor hydroxyl groups at the 3' end of a tRNA effector. We describe here the isolation of a DNA aptamer that specifically induced hydrolysis of a misactivated amino acid bound to a tRNA synthetase. The aptamer had no effect on the stability of the correctly activated amino acid and was almost as efficient as the tRNA for inducing editing activity. The aptamer has no sequence similarity to that of the tRNA effector and cannot be folded into a tRNA-like structure. These and additional data show that active acceptor hydroxyl groups in a tRNA effector and a tRNA-like structure are not essential for editing. Thus, specific bases in a nucleic acid effector trigger the editing response.

C-terminal zinc-containing peptide required for RNA recognition by a class I tRNA synthetase

Escherichia coli isoleucyl-tRNA synthetase is one of five closely related class I tRNA synthetases. The active site of the 939 amino acid polypeptide is in an N-terminal domain which contains an insertion believed essential for interactions with the tRNA acceptor helix. The enzyme was shown previously to contain an essential (for function in vivo) zinc bound to a Cys4 cluster at the C-terminal end of the polypeptide. The specific function of this zinc has been unknown. We show here that aminoacylation activity can be reconstituted in vitro by combining a 53 amino acid zinc-containing C-terminal peptide with a protein consisting of the remaining 886 amino acids. Reconstitution of aminoacylation is zinc-dependent. In contrast, the zinc-containing peptide is dispensable for synthesis of isoleucyl adenylate. Affinity coelectrophoresis showed that the 53 amino acid C-terminal peptide is required specifically for tRNA binding. We propose that the zinc-containing peptide curls back to the active site to make contact with the acceptor helix of bound tRNA, but not with isoleucine or ATP. It is the first example of a zinc-containing peptide in a class I tRNA synthetase that is essential for tRNA binding interactions. The design of this enzyme may be part of a more general scheme for class I tRNA synthetases to acquire acceptor helix binding elements during the development of the genetic code.

Single sequence of a helix-loop peptide confers functional anticodon recognition on two tRNA synthetases

The specific aminoacylation of RNA oligonucleotides whose sequences are based on the acceptor stems of tRNAs can be viewed as an operational RNA code for amino acids that may be related to the development of the genetic code. Many synthetases also have direct interactions with tRNA anticodon triplets and, in some cases, these interactions are thought to be essential for aminoacylation specificity. In these instances, an unresolved question is whether interactions with parts of the tRNA outside of the anticodon are sufficient for decoding genetic information. Escherichia coli isoleucyl- and methionyl-tRNA synthetases are closely related enzymes that interact with their respective anticodons. We used binary combinatorial mutagenesis of a 10 amino acid anticodon binding peptide in these two enzymes to identify composite sequences that would confer function to both enzymes despite their recognizing different anticodons. A single peptide was found that confers function to both enzymes in vivo and in vitro. Thus, even in enzymes where anticodon interactions are normally important for distinguishing one tRNA from another, these interactions can be 'neutralized' without losing specificity of amino-acylation. We suggest that acceptor helix interactions may play a role in providing the needed specificity.

Synthesis of cysteine-containing dipeptides by aminoacyl-tRNA synthetases

Arginyl-tRNA synthetase (ArgRS) catalyses AMP- and PPi-independent deacylation of Arg-tRNAArg in the presence of cysteine. A dipeptide, Arg-Cys, is a product of this deacylation reaction. Similar reaction with homocysteine yields Arg-Hcy. Arginine is a noncompetitive inhibitor of the cysteine-dependent deacylation which indicates that cysteine binds to the enzyme-Arg-tRNAArg complex at a site separate from the arginine binding site. In the presence of arginine, [14C]Arg-tRNAArg is deacylated at a rate similar to the rate of its spontaneous deacylation in solution and [14C]arginine is a product. Experiments with cysteine derivatives indicate that the -SH group is essential for the reaction whereas -NH2 and -COOH groups are not. Thioesters of arginine are formed with 3-mercaptopropionic acid, N-acetyl-L-cysteine and dithiothreitol. These data suggest that formation of the dipeptide Arg-Cys involves a thioester intermediate, S-(L-arginyl)-L-cysteine, which is not observed because of the rapid rearrangement to form a stable peptide bond. Facile intramolecular reaction results from the favorable geometric arrangement of the alpha-amino group of cysteine with respect to the thioester formed in the initial reaction. Similar reactions, yielding Ile-Cys and Val-Cys, are catalyzed by isoleucyl- and valyl-tRNA synthetases, respectively.

Mutation of the carboxy terminal zinc finger of E. coli isoleucyl-tRNA synthetase alters zinc binding and aminoacylation activity

Escherichia coli isoleucyl-tRNA synthetase has been shown to contain two enzyme-bound zinc atoms per polypeptide chain. To investigate the structural and functional significance of the C-terminal enzyme-bound zinc, mutagenesis was used to alter Cys 922 to Ser [IleRS(C922S)] and to replace Cys 922 through Ala 939 with a 33 amino acid peptide unable to bind zinc (AIleRS). Both IleRS(C922S) and AIleRS were found to contain only a single enzyme-bound zinc per polypeptide chain. Substitution of Co2+ for Zn2+ in IleRS(C922S) gave a visible spectrum characteristic of that expected for a single tetrahedrally coordinated enzyme-bound Co2+ atom. Little or no effect on the Km values for ATP or Ile and only a 5 fold reduction of the (kcat/Km)Ile was observed for IleRS(C922S) and AIleRS in the isoleucine-dependent ATP-pyrophosphate exchange reaction. In the tRNA-dependent aminoacylation reaction, Km values for tRNA(Ile) were only slightly affected in the mutant proteins. However, kcat/Km values were decreased approximately 200 and 2500 fold for IleRS(C922S) and AIleRS, respectively. These results suggest that both the C-terminal enzyme-bound zinc and the C-terminal peptide play important roles in aminoacylation of tRNA(Ile).

Residues in a class I tRNA synthetase which determine selectivity of amino acid recognition in the context of tRNA

Certain aminoacyl-tRNA synthetases discriminate between closely similar amino acids by hydrolytic editing reactions in the presence of their cognate tRNA. An example is the class I isoleucyl-tRNA synthetase. We recently showed that a mutation which eliminates discrimination between isoleucine (Ile) and valine (Val) in the initial amino acid binding and activation steps had little effect on the hydrolytic editing of activated valine in the presence of isoleucine tRNA (tRNA(Ile)). The results showed that initial amino acid binding and discrimination are functionally independent of tRNA-dependent amino acid discrimination. In this work, we cross-linked (to isoleucyl-tRNA synthetase) a reactive analog of valine misacylated onto tRNA(Ile). Mutation of specific residues within a peptide segment identified by the cross-linking analysis severely affected discrimination of Val-tRNA(Ile) versus Ile-tRNA(Ile). The mutationally sensitive residues are part of an insertion into the catalytic domain and are themselves completely conserved among all known prokaryotic and eukaryotic sequences of the enzyme.

Switching recognition of two tRNA synthetases with an amino acid swap in a designed peptide

The genetic code is based on specific interactions between transfer RNA (tRNA) synthetases and their cognate tRNAs. The anticodons for methionine and isoleucine tRNAs differ by a single nucleotide, and changing this nucleotide in an isoleucine tRNA is sufficient to change aminoacylation specificity to methionine. Results of combinatorial mutagenesis of an anticodon-binding-helix loop peptide were used to design a hybrid sequence composed of amino acid residues from methionyl- and isoleucyl-tRNA synthetases. When the hybrid sequence was transplanted into isoleucyl-tRNA synthetase, active enzyme was generated in vivo and in vitro. The transplanted peptide did not confer function to methionyl-tRNA synthetase, but the substitution of a single amino acid within the transplanted peptide conferred methionylation and prevented isoleucylation. Thus, the swap of a single amino acid in the transplanted peptide switches specificity between anticodons that differ by one nucleotide.

Thiol ligation of two zinc atoms to a class I tRNA synthetase: evidence for unshared thiols and role in amino acid binding and utilization

Class I tRNA synthetases generally contain a characteristic N-terminal catalytic core joined to a C-terminal domain that is idiosyncratic to the enzyme. The closely related class I Escherichia coli methionyl- and isoleucyl-tRNA synthetases each have a single zinc atom coordinated to ligands contained in the catalytic domain. Isoleucyl-tRNA synthetase has a second, functionally essential, zinc bound to ligands at the C-terminal end of the 939 amino acid polypeptide. Recent evidence suggested that this structure curls back and interacts directly or indirectly with the active site. We show here by X-ray absorption spectroscopy that the average Zn environment contains predominantly sulfur ligands with a Zn-S distance of 2.33 A. A model with eight coordinated thiolates divided between two Zn(Cys)4 structures best fit the data which are not consistent with a thiolate-bridged Zn2(Cys)6 structure joining the C-terminal end with the N-terminal active site domain. We also show that zinc bound to the N-terminal catalytic core is important specifically for amino acid binding and utilization, although a direct interaction with zinc is unlikely. We suggest that, in addition to idiosyncratic sequences for tRNA acceptor helix interactions incorporated into the class-defining catalytic domain common to class I enzymes, the architecture of at least some parts of the amino acid binding sites may differ from enzyme to enzyme and include motifs that bind zinc.

Zinc-dependent cell growth conferred by mutant tRNA synthetase

We present evidence that zinc bound near the C terminus of a long tRNA synthetase polypeptide, and at a location far in the sequence from the catalytic domain, is needed to sustain cell growth and is, therefore, essential for enzyme function. Several class I and class II tRNA synthetases contain bound zinc, including the 939-amino acid class I Escherichia coli isoleucyl-tRNA synthetase, which has two zinc atoms coordinated to cysteine sulfhydryls. The functional significance of these bound zinc atoms has been unclear. Like other class I tRNA synthetases, the isoleucine enzyme has a class-defining conserved N-terminal domain that contains the catalytic site. The C-terminal domain is variable in sequence and structure and not conserved among all of the class I enzymes. Using split proteins, we localized a zinc binding site to the C-terminal end of isoleucyl-tRNA synthetase. Serine substitutions of single cysteines at a thiol-containing putative zinc binding site that is less than 40 amino acids from the C terminus confer a zinc-dependent growth phenotype on cells harboring the mutant enzymes. We propose that zinc bound near the C terminus is part of a structure that interacts directly or indirectly with the active site. A structure at the C terminus that provides a functional link between the conserved N-terminal catalytic and non-conserved C-terminal domain may be common to several class I enzymes.

Human cytoplasmic isoleucyl-tRNA synthetase: selective divergence of the anticodon-binding domain and acquisition of a new structural unit

We show here that the class I human cytoplasmic isoleucyl-tRNA synthetase is an exceptionally large polypeptide (1266 aa) which, unlike its homologues in lower eukaryotes and prokaryotes, has a third domain of two repeats of an approximately 90-aa sequence appended to its C-terminal end. While extracts of Escherichia coli do not aminoacrylate mammalian tRNA with isoleucine, expression of the cloned human gene in E. coli results in charging of the mammalian tRNA substrate. The appended third domain is dispensable for detection of this aminoacylation activity and may be needed for assembly of a multisynthetase complex in mammalian cells. Alignment of the sequences of the remaining two domains shared by isoleucyl-tRNA synthetases from E. coli to human reveals a much greater selective pressure on the domain needed for tRNA acceptor helix interactions and catalysis than on the domain needed for interactions with the anticodon. This result may have implications for the historical development of an operational RNA code for amino acids.

Mutational isolation of a sieve for editing in a transfer RNA synthetase

Editing reactions are essential for the high fidelity of information transfer in processes such as replication, RNA splicing, and protein synthesis. The accuracy of interpretation of the genetic code is enhanced by the editing reactions of aminoacyl transfer RNA (tRNA) synthetases, whereby amino acids are prevented from being attached to the wrong tRNAs. Amino acid discrimination is achieved through sieves that may overlap with or coincide with the amino acid binding site. With the class I Escherichia coli isoleucine tRNA synthetase, which activates isoleucine and occasionally misactivates valine, as an example, a rationally chosen mutant enzyme was constructed that lacks entirely its normal strong ability to distinguish valine from isoleucine by the initial amino acid recognition sieve. The misactivated valine, however, is still eliminated by hydrolytic editing reactions. These data suggest that there is a distinct sieve for editing that is functionally independent of the amino acid binding site.

Molecular recognition of the identity-determinant set of isoleucine transfer RNA from Escherichia coli

Molecular recognition of Escherichia coli tRNA(Ile) by the cognate isoleucyl-tRNA synthetase (IleRS) was studied by analyses of chemical footprinting with N-nitroso-N-ethylurea and aminoacylation kinetics of variant tRNA(Ile) transcripts prepared with bacteriophage T7 RNA polymerase. IleRS binds to the acceptor, dihydrouridine (D), and anticodon stems as well as to the anticodon loop. The "complete set" of determinants for the tRNA(Ile) identity consists of most of the nucleotides in the anticodon loop (G34, A35, U36, t6A37 and A38), the discriminator nucleotide (A73), and the base-pairs in the middle of the anticodon, D and acceptor stems (C29.G41, U12.A23 and C4.G69, respectively). As for the tertiary base-pairs, two are indispensable for the isoleucylation activity, whereas the others are dispensable. Correspondingly, some of the phosphate groups of these dispensable tertiary base-pair residues were shown to be exposed to N-nitroso-N-ethylurea when tRNA(Ile) was bound with IleRS. Furthermore, deletion of the T psi C-arm only slightly impaired the tRNA(Ile) activity. Thus, it is proposed that the recognition by IleRS of all the widely distributed identity determinants is coupled with a global conformational change that involves the loosening of a particular set of tertiary base-pairs of tRNA(Ile).

Probing the metal binding sites of Escherichia coli isoleucyl-tRNA synthetase

The metal binding properties of isoleucyl-tRNA synthetase (IleRS) from Escherichia coli were studied by in vivo substitution of the enzyme-bound metals. Purified E. coli IleRS was shown to have two tightly bound zinc atoms per active site. Cobalt- and cadmium-substituted IleRS were also found to contain two tightly bound Co2+ and Cd2+ atoms per polypeptide chain, respectively. The d-d transitions in the low energy absorption spectrum of Co(2+)-substituted IleRS were characteristic of that expected for two tetrahedrally coordinated Co2+ metals. Apo-IleRS was found to be inactive in both the aminoacylation of tRNA(Ile) and in the isoleucine-dependent ATP-pyrophosphate exchange reactions. Both Co(2+)- and Cd(2+)-substituted IleRS were found to have kcat/Km values in the isoleucine-dependent ATP-pyrophosphate exchange assay approximately 5-fold lower than the native Zn2+ enzyme. A single enzyme-bound Zn2+ or Co2+ atom per polypeptide chain could be removed by dialysis of Zn(2+)- or Co(2+)-substituted IleRS against 1,10-phenanthroline. Removal of one of the two enzyme-bound Zn2+ atoms per polypeptide chain with 1,10-phenanthroline was found to decrease (kcat/Km)Ile by approximately 130-fold. The dependence of the kinetic parameters on the identity and number of enzyme-bound metals in the isoleucine-dependent ATP-pyrophosphate exchange reaction suggests that at least one enzyme-bound metal is indirectly involved in aminoacyladenylate formation. Metal substitution or removal of one of the two enzyme-bound metals in IleRS was found to have little effect on the Km value for tRNA(Ile) or the kcat value for aminoacylation of tRNA(Ile).(ABSTRACT TRUNCATED AT 250 WORDS)

Modification of aminoacyl-tRNA synthetases with pyridoxal-5'-phosphate. Identification of the labeled amino acid residues

The isotopic [32P]PPi-ATP exchange activity of isoleucyl-, valyl-, histidyl-, tyrosyl- and methionyl-tRNA synthetases from Escherichia coli are lost upon incubation in the presence of pyridoxal-5'-phosphate (PLP). When the residual activity of either isoleucyl-, valyl- or methionyl-tRNA synthetase (monomeric truncated form) was plotted as a function of the number of PLP molecules incorporated per enzyme molecule, the plots obtained appeared biphasic. Below 50% inactivation of these enzymes, PLP incorporation varied linearly with the isotopic exchange measurements, and extrapolation of the first half of the plot indicated a stoichiometry of 1.10 +/- 0.05 mol of PLP incorporated per mol of 100% inactivated synthetase. Beyond 50% inactivation, the graph deviated from its initial slope, and up to 4-5 mol of PLP were incorporated per mol of synthetase at the highest used PLP concentrations. In the cases of homodimeric histidyl- and tyrosyl-tRNA synthetases, extrapolation of the graph at 100% inactivation indicated 2.8 +/- 0.1 and 2.4 +/- 0.1 mol of PLP incorporated per mol of enzyme, respectively. PLP-labeled peptides were obtained through trypsin digestion and RPLC purification, prior to Edman degradation analysis. PLP-labeled residues were identified as lysines 132, 332, 335 and 402 of monomeric methionyl-tRNA synthetase, lysines 332, 335, 402, 465, 596 and 640 of native dimeric methionyl-tRNA synthetase, lysines 22, 117, 601, 604 and 645 of isoleucyl-tRNA synthetase, lysines 554, 557, 559, 593 and 909 of valyl-tRNA synthetase, lysines 2, 118, 369 and 370 of histidyl-tRNA synthetase, and lysine 237 of tyrosyl-tRNA synthetase. In addition, the amino terminal residue of the polypeptide chain(s) of either isoleucyl-, valyl-, histidyl- or methionyl-tRNA synthetases was found labeled. Among these residues, lysines 332, 335 and 402 of monomeric methionyl-tRNA synthetase as well as lysines 332, 335, 402 and 596 of dimeric methionyl-tRNA synthetase, lysines 601, 604 and 645 of isoleucyl-tRNA synthetase, lysines 554, 557 and 559 of valyl-tRNA synthetase, lysines 2, 369 and 370 of histidyl-tRNA synthetase, and lysine 237 of tyrosyl-tRNA synthetase were labeled in the presence of PLP concentrations smaller than or equal to 1 mM, and are shown to be critical for the activity of the enzymes. It is concluded that these residues participate to the binding sites of the phosphates of ATP on the studied synthetases.

Fast protein sequence verification by matrix assisted laser desorption mass spectrometric analysis of whole enzymatic digests

Matrix assisted laser desorption mass spectrometry provides a very fast and efficient way to check protein sequences by the analysis of whole proteolytic digests. This method has been applied to the sequence verification of E. coli isoleucyl tRNA synthetase, for which two different sequences are found in data banks. The result of this investigation clearly shows that no one of these sequences is correct.

Evidence for distinct locations for metal binding sites in two closely related class I tRNA synthetases

Of the ten class I tRNA synthetases, those for methionine and isoleucine are among the most closely related. In recent work we showed that the 676 amino acid E. coli methionine tRNA synthetase has one zinc bound per polypeptide. Zinc may be replaced by spectroscopically observable cobalt with retention of full activity. Bound zinc has been localized to a cysteine cluster within an insertion into the nucleotide binding fold that characterizes all class I enzymes. Mutations which interfere with metal ligation to these cysteines yield proteins that are defective in activity. Additional data presented here show that change of the cobalt oxidation state and coordination geometry of the Co(II)-substituted enzyme results in a complete loss in activity, and that mutations which replace any one of the zinc-binding cysteine sulfhydryls have a small but measurable effect on protein stability. These results further support the importance of the metal for the active site. We also show that, in contrast to methionine tRNA synthetase, the closely related but larger 939 amino acid E. coli isoleucine tRNA synthetase contains 1.5 to 2 molecules of zinc bound per polypeptide. The cobalt-substituted enzyme is active and shows the expected spectrum for tetrahedral coordination to sulfur ligands. Although the site(s) for metal coordination in isoleucine tRNA synthetase has not been rigorously established, one likely sequence element is in a region of the primary structure different from the known metal binding site in methionine tRNA synthetase. Thus, these two closely related proteins have incorporated metal binding sites into distinct parts of their related sequences.

Transcription of the ileS operon in the archaeon Methanobacterium thermoautotrophicum Marburg

In the thermophilic archaeon Methanobacterium thermoautotrophicum Marburg, the structural gene for isoleucyl-tRNA synthetase (ileS) is flanked upstream by orf401 and downstream by purL. orf401 encodes a 43.5-kDa protein with an unknown function. Northern (RNA) hybridization and S1 nuclease protection experiments showed that the orf401, ileS, and purL genes are cotranscribed from an archael consensus promoter in front of orf401. The corresponding transcript was about eightfold increased in cells that had been exposed to pseudomonic acid A, a specific inhibitor of isoleucyl-tRNA synthetase. Growth inhibition by puromycin, tryptophan starvation, or starvation for hydrogen did not affect the level of this transcript. The level of a trpE transcript, however, was drastically elevated upon tryptophan starvation, while inhibition by pseudomonic acid A had no effect on the level of this transcript. Expression of ileS thus appears to be controlled by a regulatory mechanism which specifically responds to the availability of isoleucyl-tRNA. Extensive decay of the orf401-ileS-purL message was observed. Degradation occurred, presumably by endonucleolytic cleavage, within the orf401 region.

High-level mupirocin resistance in Staphylococcus aureus: evidence for two distinct isoleucyl-tRNA synthetases

Mupirocin resistance in Staphylococcus aureus results from changes in the target enzyme, isoleucyl-tRNA synthetase (IRS). Twelve strains of S. aureus comprising four susceptible (MICs < or = 4 micrograms/ml), four intermediate level-resistant (MICs between 8 and 256 micrograms/ml), and four highly resistant (MICs > or = 512 micrograms/ml) isolates were examined for their IRS content and the presence of a gene known to encode high-level mupirocin resistance. Ion-exchange chromatography of cell extracts showed a single IRS active peak in mupirocin-susceptible strains, with 50% inhibitory concentrations (IC50s) of 0.7 to 3.0 ng of mupirocin per ml. In strains showing intermediate mupirocin resistance, similar single IRS activity peaks were observed, but these were less sensitive to inhibition, and the mupirocin IC50s for them were 19 to 43 ng/ml. Strains that were highly resistant to mupirocin displayed two distinct peaks; one was similar to that found with susceptible strains (IC50, 0.9 to 2.5 ng/ml), but an additional peak with an IC50 of 7,000 to 10,000 ng/ml was also observed. A strain cured of the plasmid encoding high-level mupirocin resistance lacked the resistant IRS peak. Restriction digests, produced by endonuclease NcoI, of total bacterial DNA isolated from the highly resistant strains hybridized with a mupirocin resistance gene probe, whereas DNA isolated from the intermediate level-resistant and susceptible strains did not. These results demonstrate that two different IRS enzymes were present in highly mupirocin-resistant S. aureus strains. In strains expressing intermediate levels of resistance, only a chromosomally encoded IRS which was inhibited less by mupirocin than IRS from fully susceptible strains was detected.

A 15N-1H nuclear magnetic resonance study on the interaction between isoleucine tRNA and isoleucyl-tRNA synthetase from Escherichia coli

Imino 15N and 1H resonances of Escherichia coli tRNA(lIle) were observed in the absence and presence of E coli isoleucyl-tRNA synthetase. Upon complex formation of tRNA(lIle) with isoleucyl-tRNA synthetase, some imino 15N-1H resonances disappeared, and some others were significantly broadened and/or shifted in the 1H chemical shift, while the others were observed at the same 15N-1H chemical shifts. It was indicated that the binding of tRNA(lIle) with IleRS affect the following four regions: the anticodon stem, the junction of the acceptor and T stems, the middle of the D stem, and the region where the tertiary base pair connects the T, D, and extra loops. This result is consistent with those of chemical footprinting and site-directed mutagenesis studies. Taken together, these three independent results reveal the recognition mechanism of tRNA(lIle) by IleRS: IleRS recognizes all the identity determinants distributed throughout the tRNA(lIle) molecule, which induces changes in the secondary and tertiary structures of tRNA(lIle).

Effect of inorganic pyrophosphate on the pretransfer proofreading in the isoleucyl-tRNA synthetase from Escherichia coli

A total rate equation was used to calculate the discrimination of valine by the isoleucyl-tRNA synthetase from Escherichia coli. The PPi present in the cell makes the backward reaction or the pyrophosphorolysis of the E.aa-AMP possible. If the E.Ile-AMP has been corrected for wrong aminoacyl adenylation by the pretransfer proofreading, the pyrophosphorolysis rapidly equilibrates the corrected E.Ile-AMP with E.Ile and thus spoils the effect of the proofreading. The loss of the corrected species is avoided if there is a barrier (perhaps conformational) formed by a slow reaction step between the noncorrected E.Ile-AMP and the corrected (*E)tRNA(Ile-AMP). If such a slow conformational change exists, the increase in accuracy from the pretransfer proofreading would be beneficial, and, in addition, the PPi increases the accuracy by optimizing the initial discrimination of the wrong amino acid.

Analysis of the isoleucyl-tRNA synthetase reaction by total rate equations. Magnesium and spermidine in the tRNA kinetics

Derivation of a steady-state rate equation for the aminoacyl-tRNA synthetases is described, and its suitability for the analysis of various details of the reaction is tested. The equation is applied to the magnesium and spermidine dependences of the isoleucyl-tRNA synthetase reaction. Earlier work [Airas, R.K. (1990) Eur. J. Biochem. 192, 401-409] is expanded by experiments and calculations of the tRNA kinetics. The analysis suggests the following new details in addition to the earlier results: (a) The binding of tRNA to the enzyme (and not only the rate of the aminoacylation reaction) is affected by the presence of the Mg2+ and spermidine in the tRNA molecule. At least two bound Mg2+ or spermidines are required. (b) tRNA and PPi partly inhibit the binding of each other to the enzyme. (c) The transfer reaction is rather slow, and, at least under some conditions, it participates in rate limitation. (d) A Mg(2+)-induced reduction in the aminoacylation rate seems to be directed to the dissociation of the aminoacyl-tRNA from the enzyme. This dissociation rate is enhanced if a Mg2+ is first dissociated from the enzyme or tRNA. An increase in the Mg2+ concentration shifts the rate limitation from the transfer reaction towards dissociation of the product.