Methionyl-tRNA synthetase shows the nucleotide binding fold observed in dehydrogenases

Structural diversity and protein engineering of the aminoacyl-tRNA synthetases

Aminoacyl-tRNA synthetases (aaRS) are the enzymes that ensure faithful transmission of genetic information in all living cells, and are central to the developing technologies for expanding the capacity of the translation apparatus to incorporate nonstandard amino acids into proteins in vivo. The 24 known aaRS families are divided into two classes that exhibit functional evolutionary convergence. Each class features an active site domain with a common fold that binds ATP, the amino acid, and the 3'-terminus of tRNA, embellished by idiosyncratic further domains that bind distal portions of the tRNA and enhance specificity. Fidelity in the expression of the genetic code requires that the aaRS be selective for both amino acids and tRNAs, a substantial challenge given the presence of structurally very similar noncognate substrates of both types. Here we comprehensively review central themes concerning the architectures of the protein structures and the remarkable dual-substrate selectivities, with a view toward discerning the most important issues that still substantially limit our capacity for rational protein engineering. A suggested general approach to rational design is presented, which should yield insight into the identities of the protein-RNA motifs at the heart of the genetic code, while also offering a basis for improving the catalytic properties of engineered tRNA synthetases emerging from genetic selections.

Toward understanding phosphoseryl-tRNACys formation: the crystal structure of Methanococcus maripaludis phosphoseryl-tRNA synthetase

A number of archaeal organisms generate Cys-tRNA(Cys) in a two-step pathway, first charging phosphoserine (Sep) onto tRNA(Cys) and subsequently converting it to Cys-tRNA(Cys). We have determined, at 3.2-A resolution, the structure of the Methanococcus maripaludis phosphoseryl-tRNA synthetase (SepRS), which catalyzes the first step of this pathway. The structure shows that SepRS is a class II, alpha(4) synthetase whose quaternary structure arrangement of subunits closely resembles that of the heterotetrameric (alphabeta)(2) phenylalanyl-tRNA synthetase (PheRS). Homology modeling of a tRNA complex indicates that, in contrast to PheRS, a single monomer in the SepRS tetramer may recognize both the acceptor terminus and anticodon of a tRNA substrate. Using a complex with tungstate as a marker for the position of the phosphate moiety of Sep, we suggest that SepRS and PheRS bind their respective amino acid substrates in dissimilar orientations by using different residues.

Aminoacylation of tRNA in the evolution of an aminoacyl-tRNA synthetase

Aminoacyl-tRNA synthetases catalyze aminoacylation of tRNAs by joining an amino acid to its cognate tRNA. The selection of the cognate tRNA is jointly determined by separate structural domains that examine different regions of the tRNA. The cysteine-tRNA synthetase of Escherichia coli has domains that select for tRNAs containing U73, the GCA anticodon, and a specific tertiary structure at the corner of the tRNA L shape. The E. coli enzyme does not efficiently recognize the yeast or human tRNACys, indicating the evolution of determinants for tRNA aminoacylation from E. coli to yeast to human and the coevolution of synthetase domains that interact with these determinants. By successively modifying the yeast and human tRNACys to ones that are efficiently aminoacylated by the E. coli enzyme, we have identified determinants of the tRNA that are important for aminoacylation but that have diverged in the course of evolution. These determinants provide clues to the divergence of synthetase domains. We propose that the domain for selecting U73 is conserved in evolution. In contrast, we propose that the domain for selecting the corner of the tRNA L shape diverged early, after the separation between E. coli and yeast, while that for selecting the GCA-containing anticodon loop diverged late, after the separation between yeast and human.

The class II aminoacyl-tRNA synthetases and their active site: evolutionary conservation of an ATP binding site

Previous sequence analyses have suggested the existence of two distinct classes of aminoacyl-tRNA synthetase. The partition was established on the basis of exclusive sets of sequence motifs (Eriani et al. [1990] Nature 347:203-306). X-ray studies have now well defined the structural basis of the two classes: the class I enzymes share with dehydrogenases and kinases the classic nucleotide binding fold called the Rossmann fold, whereas the class II enzymes possess a different fold, not found elsewhere, built around a six-stranded antiparallel beta-sheet. The two classes of synthetases catalyze the same global reaction that is the attachment of an amino acid to the tRNA, but differ as to where on the terminal adenosine of the tRNA the amino acid is placed: class I enzymes act on the 2' hydroxyl whereas the class II enzymes prefer the 3' hydroxyl group. The three-dimensional structure of aspartyl-tRNA synthetase from yeast, a typical class II enzyme, is described here, in relation to its function. The crucial role of the sequence motifs in substrate binding and enzyme structure is high-lighted. Overall these results underline the existence of an intimate evolutionary link between the aminoacyl-tRNA synthetases, despite their actual structural diversity.

Methionine as translation start signal: a review of the enzymes of the pathway in Escherichia coli

Methionine is the universal translation start but the first methionine is removed from most mature proteins. This review focuses on our present knowledge of the five enzymes sustaining the methionine pathway in translation initiation in Escherichia coli: methionyl-tRNA synthetase, methionyl-tRNA(fMet) formyltransferase, peptidyl-tRNA hydrolase, peptide deformylase and methionine aminopeptidase. The possible significance of retaining methionine as initiation signal is discussed.

Activation of methionine by Escherichia coli methionyl-tRNA synthetase

In the present work, we have examined the function of three amino acid residues in the active site of Escherichia coli methionyl-tRNA synthetase (MetRS) in substrate binding and catalysis using site-directed mutagenesis. Conversion of Asp52 to Ala resulted in a 10,000-fold decrease in the rate of ATP-PPi exchange catalyzed by MetRS with little or no effect on the Km's for methionine or ATP or on the Km for the cognate tRNA in the aminoacylation reaction. Substitution of the side chain of Arg233 with that of Gln resulted in a 25-fold increase in the Km for methionine and a 2000-fold decrease in kcat for ATP-PPi exchange, with no change in the Km for ATP or tRNA. These results indicate that Asp52 and Arg233 play important roles in stabilization of the transition state for methionyl adenylate formation, possibly directly interacting with complementary charged groups (ammonium and carboxyl) on the bound amino acid. Primary sequence comparisons of class I aminoacyl-tRNA synthetases show that all but one member of this group of enzymes has an aspartic acid residue at the site corresponding to Asp52 in MetRS. The synthetases most closely related to MetRS (including those specific for Ile, Leu, and Val) also have a conserved arginine residue at the position corresponding to Arg233, suggesting that these conserved amino acids may play analogous roles in the activation reaction catalyzed by each of these enzymes. Trp305 is located in a pocket deep within the active site of MetRS that has been postulated to form the binding cleft for the methionine side chain.(ABSTRACT TRUNCATED AT 250 WORDS)

Alanyl-tRNA synthetase from Escherichia coli, Bombyx mori and Ratus ratus. Existence of common structural features

Alanyl-tRNA synthetase from Escherichia coli, Bombyx mori and rat were examined with respect to the following functional and structural properties: the effect of substrates on sensitivity to proteolysis, secondary structure as determined by circular dichroism, amino acid composition and, in the case of the rat and insect enzymes, partial amino acid sequence determination on a 60-kDa C-terminal tryptic fragment. Digestion of the enzyme from all three sources with trypsin resulted in significant decline in aminoacyl-tRNA synthetase activity with little effect on pyrophosphate-exchange activity. In each case the presence of alanine and ATP together, but not separately, reduced the rate of digestion by trypsin; the largest effect was observed with the enzyme from rat liver. Trypsin digestion generated fragments of 47 kDa and 40 kDa with all three enzymes, but detection of significant quantities of the 47-kDa fragment from the rat enzyme required the presence of ATP and alanine. Trypsin digestion produced a fragment of 60 kDa with all three enzymes, but detection of significant quantities of this fragment with the bacterial enzyme required the presence of ATP and alanine. Limited sequence analysis of the 60-kDa fragment from the insect and rat enzymes indicated that trypsin cleaved both proteins at the same site to generate this species. Similar effects of substrates were observed when the enzymes were digested with chymotrypsin suggesting that the effects of substrates on protease sensitivity were not unique to trypsin. Circular dichroism spectra obtained for the three enzymes were qualitatively and quantitatively similar. There is some similarity in amino acid composition between the rat and insect enzymes.

Sequence determination and modeling of structural motifs for the smallest monomeric aminoacyl-tRNA synthetase

Polypeptide chains of 19 previously studied Escherichia coli aminoacyl-tRNA synthetases are as large as 951 amino acids and, depending on the enzyme, have quaternary structures of alpha, alpha 2, alpha 2 beta 2, and alpha 4. These enzymes have been organized into two classes which are defined by sequence motifs that are associated with specific three-dimensional structures. We isolated, cloned, and sequenced the previously uncharacterized gene for E. coli cysteine-tRNA synthetase (EC 6.1.1.16) and showed that it encodes a protein of 461 amino acids. Biochemical analysis established that the protein is a monomer, thus establishing this enzyme as the smallest known monomeric synthetase. The sequence shows that cysteine-tRNA synthetase is a class I enzyme that is most closely related to a subgroup that includes the much larger methionine-, isoleucine-, leucine-, and valine-tRNA synthetases, which range in size from 677 to 951 amino acids. The amino-terminal 293 amino acids of the cysteine enzyme can be modeled as a nucleotide-binding fold that is more compact than that of its closest relatives by virtue of truncations of two insertions that split the fold. This smaller nucleotide-binding fold accounts for much of the reduced size of the cysteine enzyme and establishes the limit to which the structure of this domain is contracted in the five members of this subgroup of class I enzymes.

Cysteinyl-tRNA synthetase: determination of the last E. coli aminoacyl-tRNA synthetase primary structure

The gene coding for E. coli cysteinyl-tRNA synthetase (cysS) was isolated by complementation of a strain deficient in cysteinyl-tRNA synthetase activity at high temperature (43 degrees C). Sequencing of a 2.1 kbp DNA fragment revealed an open reading frame of 1383 bp coding for a protein of 461 amino acid residues with a Mr of 52,280, a value in close agreement with that observed for the purified protein, which behaves as a monomer. The sequence of CysRS bears the canonical His-Ile- Gly -His (HIGH) and Lys-Met-Ser-Lys-Ser (KMSKS) motifs characteristic of the group of enzymes containing a Rossmann fold; furthermore, it shows striking homologies with MetRS (an homodimer of 677 residues) and to a lesser extent with Ile-, Leu-, and ValRS (monomers of 939, 860, and 951 residues respectively). With its monomeric state and smaller size, CysRS is probably more closely related to the primordial aminoacyl-tRNA synthetase from which all have diverged.

Aspartyl-tRNA synthetase from Escherichia coli: cloning and characterisation of the gene, homologies of its translated amino acid sequence with asparaginyl- and lysyl-tRNA synthetases

By screening of an Escherichia coli plasmidic library using antibodies against aspartyl-tRNA synthetase (AspRS) several clones were obtained containing aspS, the gene coding for AspRS. We report here the nucleotide sequence of aspS and the corresponding primary structure of the aspartyl-tRNA synthetase, a protein of 590 amino acid residues with a Mr 65,913, a value in close agreement with that observed for the purified protein. Primer extension analysis of the aspS mRNA using reverse transcriptase located its 5'-end at 94 nucleotides upstream of the translation initiation AUG; nuclease S1 analysis located the 3'-end at 126 nucleotides downstream of the stop codon UGA. Comparison of the DNA-derived protein sequence with known aminoacyl-tRNA sequences revealed important homologies with asparaginyl- and lysyl-tRNA synthetases from E.coli; more than 25% of their amino acid residues are identical, the homologies being distributed preferencially in the first part and the carboxy-terminal end of the molecule. Mutagenesis directed towards a consensus tetrapeptide (Gly-Leu-Asp-Arg) and the carboxy-terminal end showed that both domains could be implicated in catalysis as well as in ATP binding.

Crystallographic study at 2.5 A resolution of the interaction of methionyl-tRNA synthetase from Escherichia coli with ATP

The crystal structure of the tryptic fragment of the methionyl-tRNA synthetase from Escherichia coli, complexed with ATP, has been refined to a crystallographic R-factor of 0.220, at 2.5 A resolution (for 4433 protein atoms). In the last stages of the refinement, the simulated annealing refinement method was fully applied, contributing to a drastic improvement of the model and the identification of the missing atoms. In the final model, the root-mean-square deviation from ideality for bond distances is 0.021 A and for angle distances is 0.054 A. The position of the zinc ion has been confirmed and is located near the active site. The tryptic fragment is composed of two globular domains. The first domain, from the N terminus to Thr360, contains a nucleotide-binding fold into which two long polypeptides of 101 and 70 residues are inserted. The nucleotide-binding fold is strengthened by the presence of the zinc ion in the vicinity of the active site. The second domain, up to Pro526, is mainly alpha-helical. The C-terminal polypeptide, Phe527 to Lys551, folds back towards the first domain, making a link between the two domains. The heptapeptide 528-534 partly shapes a deep cavity that plunges into the central core of the nucleotide-binding fold, where the ATP molecule is located. The adenine ring, deeply buried in the bottom of the cleft, is blocked between the first helix HA, and the strands A and D of the beta-sheet and makes no polar interaction with the enzyme. The 2' and 3' hydroxyl groups of the ribose, whose conformation is C2' endo, interact with the main-chain carbonyl oxygen atoms of Ile231 and Glu241, respectively. The side-chain nitrogen atom of Lys142 is at hydrogen-bonding distance from the ring oxygen O-4' of the ribose. One of the alpha-phosphate oxygen atoms and one of the gamma-phosphate oxygen atoms interact with the imidazole ring of His21, which is well conserved in many of the known synthetases; this indicates a possible crucial role for this residue in binding ATP. The beta-phosphate group is linked to the main-chain carbonyl oxygen atom of Tyr15 through an intermediate water molecule. The gamma-phosphate group interacts with the carbonyl oxygen atom and the side-chain of Asn17.(ABSTRACT TRUNCATED AT 400 WORDS)

Mapping of the active site of Escherichia coli methionyl-tRNA synthetase: identification of amino acid residues labeled by periodate-oxidized tRNA(fMet) molecules having modified lengths at the 3'-acceptor end

Initiator tRNA molecules modified at the 3'-end and lacking either the A76 (tRNA-C75), the C75-A76 (tRNA-C74), the C74-C75-A76 (tRNA-A73), or the A73-C74-C75-A76 (tRNA-A72) nucleotides were prepared stepwise by repeated periodate, lysine, and alkaline phosphatase treatments. When incubated with trypsin-modified methionyl-tRNA synthetase (MTST), excess amounts of the dialdehyde derivative of each of these shortened tRNAs (tRNA-C75ox, tRNA-C74ox, tRNA-A73ox, and tRNA-A72ox) abolished both the isotopic [32P]PPi-ATP exchange and the tRNA aminoacylation activities of the enzyme. In the presence of limiting concentrations of the various tRNAox species, the relative extents of inactivation of the enzyme were consistent with the formation of 1:1 complexes of the reacting tRNAs with the monomeric modified synthetase. Specificity of the labeling was further established by demonstrating that tRNA-C75ox binds the enzyme with an equilibrium constant and stoichiometry values in good agreement with those for the binding of nonoxidized tRNA-C75. The peptides of MTST labeled with either tRNA-C75ox or tRNA-C74ox were identified. The chymotryptic digestion of the covalent MTST.[14C]tRNA-C75ox complex yielded four peptides (A-D). In the case of tRNA-C74ox, only two of the above peptides (C and D) were identified. Peptides A, B, C, and D corresponded to fragments Ser334-Phe340, Lys61-Leu65, Val141-Tyr165, and Glu433-Phe437, respectively, in the MTST primary structure.(ABSTRACT TRUNCATED AT 250 WORDS)

Methionyl-tRNA synthetase from E. coli--a review

Methionyl-tRNA synthetase (MetRS) from E coli is a dimer composed of 2 identical subunits of Mr 76 kDa. A fully active monomeric fragment (64 kDa) could be obtained by mild proteolysis of the native dimer. Earlier studies reviewed in Blanquet et al (1979) have compared the catalytic mechanisms of native and trypsin-modified MetRS. Moreover, the truncated form of the enzyme was crystallized and its 3-D structure solved at low resolution. In the last few years, the availability of the corresponding metG gene has facilitated the development of studies using affinity labelling and site-directed mutagenesis techniques. In parallel, the 3-D structure has been solved at a resolution of 2.5 A. These convergent approaches have allowed significant progress in the understanding of the structure-function relationships of this enzyme, and, in particular, of the rules governing the recognition of tRNA.

Yeast methionyl-tRNA synthetase: analysis of the N-terminal extension and the putative tRNA anticodon binding region by site-directed mutagenesis

Yeast methionyl-tRNA synthetase has a long N-terminal extension fused to the mononucleotide binding fold that occurs at the N-terminal end of the homologous E coli enzyme. We examined the contribution of this polypeptide region to the activity of the enzyme by creating several internal deletions in MESI which preserve the correct reading frame. The results show that 185 amino acids are dispensable for activity and stability. Removal of the next 5 residues affects the activity of the enzyme. The effect is more pronounced on the tRNA amino-acylation steps than on the adenylate formation step. The Km for ATP and methionine are unaltered, indicating that the global structure of the enzyme is maintained. The Km for tRNA increased slightly by a factor of 3, which indicates that the positioning of the tRNA on the surface of the molecule is not affected. There is, however, a great effect on the Vmax of the enzyme. Examination of the 3-D structure of the homologous E coli methionyl-tRNA synthetase indicates that the amino acid region preceding the mononucleotide binding fold does not participate directly in the catalytic cleft. It could, however, act at a distance by propagating a mutational alteration of the catalytic residues. The tRNA(Met) anticodon binding region of the E coli enzyme has recently been characterized. By mutagenesis of the topologically equivalent region in the yeast enzyme, we could identify residues that alter specifically the aminoacylation of the tRNA. Leu 658 provides a van der Waals contact that is critical for the recognition of the yeast tRNA.

Understanding structural relationships in proteins of unsolved three-dimensional structure

The locations of functionally important sequences and general structural motifs have been assigned to Ile-tRNA synthetase. However, a function has not been established for some segments of the protein (e.g., CP1). The method of structural modeling described here cannot establish the details of a 3 A crystal structure, and, in contrast to a crystal structure, the precision of the model varies according to the extent of a sequence similarity or the functional importance of a region. In Ile-tRNA synthetase, the signature sequence and the flanking regions are likely to be similar in structure to the proteins on which the model is based. For other regions, it may be possible to build a three-dimensional model by connecting well defined regions and refining the positions of the connecting elements by energy minimization. Structural modelling of this kind must be done cautiously, because the order and orientation of the elements of a structural motif can change in subtle ways. In the case of Tyr-tRNA synthetase, the beta-strand nearest the N-terminus is the outermost strand of the nucleotide binding fold; in Met-tRNA synthetase, the same strand is innermost. Furthermore, the orientation of this strand may be antiparallel (Tyr-tRNA synthetase) or parallel (Met-tRNA synthetase). Because multiple structures that differ in their orientations of structural elements are possible, the structural analogies between proteins should not be naively extrapolated without independent experimental support. As described above, some regions of proteins tolerate internal deletions and insertions. This provides further experimental support for the practice of allowing for gaps in computer-generated sequence alignments. Nevertheless, because some regions are more tolerant of insertions and deletions than others, the structural and functional significance of a region of broken alignment must be assessed carefully. All gaps in sequence alignments cannot be treated equally, and each must be evaluated within its own context. In the synthetases of known structure, structural analogy can be used to identify important functional elements. For example, the amino acid binding site of Met-tRNA synthetase might be formed, at least in part, by a peptide that encompasses Ala50; this amino acid aligns with Gly94 of the Ile-tRNA synthetase. This is an example in which results on a protein of unknown structure (Ile-tRNA synthetases) can lead to identification of a potential substrate binding site in a protein of known structure (Met-tRNA synthetase).

Insertion of new sequences into the catalytic domain of an enzyme

Activities of enzymes can be modified by the replacement of active-site amino acids with residues that strengthen specific interactions with substrates or that alter the specificity. The scope for engineered enzymes would be broadened if additional, new sequences could be inserted into a catalytic domain. Properly designed, these sequences could encode new ligand binding sites, be intermediates in the construction of chimeric enzymes, or alter the internal flexibility and "breathing" modes of the active-site region. As a first step toward this objective, we inserted oligopeptides of up to 14 amino acids into various locations within an 82 amino acid region of the adenylate synthesis domain of Escherichia coli methionyl-tRNA synthetase. These sites include ones that are flanked by sequences that are conserved between the proteins from E. coli and the yeast Saccharomyces cerevisiae and those that are essential for activity and stability. We found that all of the insertional mutants are stable and some have catalytic parameters for adenylate synthesis that are comparable to those of the wild-type enzyme. Thus, such an approach may provide for a variety of novel applications.

Construction of intra-domain chimeras of aminoacyl-tRNA synthetases

To explore new approaches to enzyme engineering, intra-domain chimeras of two aminoacyl-tRNA synthetases were constructed. Connections were made within the nucleotide folds of these enzymes at sites earlier shown either to be dispensable for activity or able to accommodate oligopeptide insertions. (R.M. Starzyk, T.A. Webster and P. Schimmel, Science 237, 1614 (1987); R.M. Starzyk, J.J. Burbaum and P. Schimmel, Biochemistry, in press). Based on the known structure of one synthetase and structural modeling of the other, the locations of the connection sites allow the possibility of functional "compound" ATP and tRNA binding sites. Of five chimeric genes which were constructed, three direct synthesis of polypeptides that accumulate in vivo. These stable hybrids provide prototypes to which mutagenesis procedures may be applied to produce enzymatically active chimeric synthetases.

Identification of an amino acid region supporting specific methionyl-tRNA synthetase: tRNA recognition

Site-directed nuclease digestion and nonsense mutations of the Escherichia coli metG gene were used to produce a series of C-terminal truncated methionyl-tRNA synthetases. Genetic complementation studies and characterization of the truncated enzymes establish that the methionyl-tRNA synthetase polypeptide (676 residues) can be reduced to 547 residues without significant effect on either the activity or the stability of the enzyme. The truncated enzyme (M547) appears to be similar to a previously described fully active monomeric from of 64,000 Mr derived from the native homodimeric methionyl-tRNA synthetase (2 x 76,000 Mr) by limited trypsinolysis in vitro. According to the crystallographic three-dimensional structure at 2.5 A resolution of this trypsin-modified enzyme, the polypeptide backbone folds into two domains. The former, the N-domain, contain a crevice that is believed to bind ATP. The latter, the C-domain, has a 28 C-residue extension (520 to 547), which folds back, toward the N-domain and forms an arm linking the two domains. This study shows that upon progressive shortening of this C-terminal extension, the enzyme thermostability decreases. This observation, combined with the study of several point mutations, allows us to propose that the link made by the C-terminal arm of M547 between its N and C-terminal domains is essential to sustain an active enzyme conformation. Moreover, directing point mutations in the 528-533 region, which overhangs the putative ATP-binding site, demonstrates that this part of the C-terminal arm participates also in the specific complexation of methionyl-tRNA synthetase with its cognate tRNAs.

Evidence that the 3' end of a tRNA binds to a site in the adenylate synthesis domain of an aminoacyl-tRNA synthetase

Aminoacylation requires that an enzyme-bound aminoacyladenylate is brought proximal to the 3' end of a specific transfer RNA. In Escherichia coli alanyl-tRNA synthetase, the first 368 amino acids encode a domain for adenylate synthesis while sequences on the carboxyl-terminal side of this domain are required for much of the enzyme-tRNAAla binding energy. The 3' end of E. coli tRNAAla has been cross-linked to the enzyme, and sequence analysis showed that Lys-73 is the major site of coupling. A mutant enzyme with a Lys-73----Gln replacement has a 50-fold reduced kcat/Km (with respect to tRNAAla) for aminoacylation but has a relatively small alteration of its kinetic parameters for ATP and alanine in the adenylate synthesis reaction. The data provide evidence that the 3' end of tRNAAla binds to a site in the enzyme domain responsible for adenylate synthesis and that a residue (Lys-73) in this domain is important for a tRNAAla-dependent step that is subsequent to the synthesis of the aminoacyladenylate intermediate.

Probing the substrate-binding sites of aminoacyl-tRNA synthetases with the procion dye green HE-4BD

A reactive bis-dichloro derivative of the Procion dye Green HE-4BD was shown to inactivate irreversibly methionyl-tRNA synthetase (MTS) from Escherichia coli and also tryptophyl-tRNA synthetase (WTS) and tyrosyl-tRNA synthetase (YTS) from Bacillus stearothermophilus at pH 8.5 and 37 degrees C. At a 5-fold excess of reactive dye over enzyme subunit concentration MTS was quantitatively inactivated within 20 min in the ATP/pyrophosphate exchange assay, whereas WTS and YTS show an 80% loss of activity over the same time period. The inactivation is affected by the addition of substrates, which either protect (WTS and YTS) or promote (YTS with tyrosine) the dye-mediated enzyme inactivation. Green HE-4BD-OH was shown to be a competitive inhibitor of MTS with respect to MgATP, methionine and tRNA substrates.

Crystallization of a small fragment of an aminoacyl tRNA synthetase

Single crystals of an amino-terminal fragment of Escherichia coli alanine tRNA synthetase have been prepared by the vapor diffusion method. The fragment extends to amino acid residue 368 and catalyzes the synthesis of alanyl adenylate. The crystals grow in the presence of alanine as rhombic plates in space group P2(1)2(1)2(1) and with unit cell dimensions of a = 67.9 A, b = 98.5 A and c = 123.6 A (1 A = 0.1 nm). They diffract to better than 3 A resolution.

A high resolution diffracting crystal form of the complex between yeast tRNAAsp and aspartyl-tRNA synthetase

Three new crystal forms of the complex between yeast tRNAAsp and aspartyl-tRNA synthetase have been produced. The best crystals, obtained after modifying both purification and crystallization conditions, belong to space group P2(1)2(1)2(1) and diffract to 2.7 A. Unit cell parameters are a = 210.4 A, b = 145.3 A and c = 86.0 A (1 A = 0.1 nm), with one dimeric enzyme and two tRNA molecules in the asymmetric unit.

Peptides at the tRNA binding site of the crystallizable monomeric form of E. coli methionyl-tRNA synthetase

A protein affinity labeling derivative of E. coli tRNA(fMet) carrying lysine-reactive cross-linking groups has been covalently coupled to monomeric trypsin-modified E. coli methionyl-tRNA synthetase. The cross-linked tRNA-synthetase complex has been isolated by gel filtration, digested with trypsin, and the tRNA-bound peptides separated from the bulk of the free tryptic peptides by anion exchange chromatography. The bound peptides were released from the tRNA by cleavage of the disulfide bond of the cross-linker and purified by reverse-phase high-pressure liquid chromatography, yielding three major peptides. These peptides were found to cochromatograph with three peptides of known sequence previously cross-linked to native methionyl-tRNA synthetase through lysine residues 402, 439 and 465. These results show that identical lysine residues are in close proximity to tRNA(fMet) bound to native dimeric methionyl-tRNA synthetase and to the crystallizable monomeric form of the enzyme, and indicate that cross-linking to the dimeric protein occurs on the occupied subunit of the 1:1 tRNA-synthetase complex.

Evidence for dispensable sequences inserted into a nucleotide fold

Previous experimental results along with the structural modeling presented indicate that a nucleotide fold starts in the amino-terminal part of Escherichia coli isoleucyl-transfer RNA synthetase, a single chain polypeptide of 939 amino acids. Internal deletions were created in the region of the nucleotide fold. A set of deletions that collectively span 145 contiguous amino acids yielded active enzymes. Further extensions of the deletions yielded inactive or unstable proteins. The three-dimensional structure of an evidently homologous protein suggests that the active deletions lack portions of a segment that connects two parts of the nucleotide fold. Therefore, the results imply that removal of major sections of the polypeptide that connects these two parts of the fold does not result in major perturbation of the nucleotide binding site.

Prohead and DNA-gp3-dependent ATPase activity of the DNA packaging protein gp16 of bacteriophage phi 29

The ATPase activity of the DNA packaging protein gp16 (gene product 16) of bacteriophage phi 29 was studied in the completely defined in-vitro assembly system. ATP was hydrolyzed to ADP and Pi in the packaging reaction that included purified proheads, DNA-gp3 and gp16. Approximately one molecule of ATP was used in the packaging of 2 base-pairs of phi 29 DNA, or 9 X 10(3) ATP molecules per virion. The hydrolysis of ATP by gp16 was both prohead and DNA-gp3 dependent. gp16 contained both the "A-type" and the "B-type" ATP-binding consensus sequences (Walker et al., 1982) and the predicted secondary structure for ATP binding. The A-type sequence of gp16 was "basic-hydrophobic region-G-X2-G-X-G-K-S-X7-hydrophobic", and similar sequences were found in the phage DNA packaging proteins gpA of lambda, gp19 of T7 and gp17 of T4. Having both the ATP-binding and potential magnesium-binding domains, all of these proteins probably function as ATPases and may have common prohead-binding capabilities. The phi 29 protein gp3, covalently bound to the DNA, may be analogous in function to proteins gpNul of lambda and gpl of phi 21 that bind the DNA.

Reaction of tryptophanyl-tRNA synthetase from beef pancreas with periodate-oxidized ATP

Tryptophanyl-tRNA synthetase from beef pancreas reacts with periodate-oxidized ATP according to biphasic kinetics. A rapid phase involves two groups of the protein, presumably lysine side-chains. The slow phase corresponds to the reaction of a larger number of groups. The time-course of the partial losses of the ATP-PPi isotopic exchange and of the aminoacylation activities of the enzyme follow the labelling of the two fast-reacting groups. However, the ability of the enzyme to form a bis(tryptophanyladenylate)-enzyme complex is not lost after reaction of these two groups with the reagent. The affinity for ATP is also unaffected by this initial labelling of the protein, as seen from the Km values of this substrate in the ATP-PPi isotopic exchange reaction. These data suggest that, in this fast initial reaction, oxidized ATP reacts neither with specific ATP-binding groups of the enzyme nor with any major catalytic residue of the tryptophan-activation site. In contrast with this first step, the further slow labelling of lysine residues leads to a disappearance of the aminoacylation ability of the enzyme, while it does not further affect the ATP-PPi exchange activity. The behaviour of beef tryptophanyl-tRNA synthetase during derivatization with oxidized ATP is therefore at variance with that which has been described for the homologous E. coli enzyme.

tRNA recognition site of Escherichia coli methionyl-tRNA synthetase

We have previously shown that anticodon bases are essential for specific recognition of tRNA substrates by Escherichia coli methionyl-tRNA synthetase (MetRS) [Schulman, L. H., & Pelka, H. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 6755-6759] and that the enzyme tightly binds to C34 at the wobble position of E. coli initiator methionine tRNA (tRNAfMet) [Pelka, H., & Schulman, L. H. (1986) Biochemistry 25, 4450-4456]. We have also previously demonstrated that an affinity labeling derivative of tRNAfMet can be quantitatively cross-linked to the tRNA binding site of MetRS [Valenzuela, D., & Schulman, L. H. (1986) Biochemistry 25, 4555-4561]. Here, we have determined the site in MetRS which is cross-linked to the anticodon of tRNAfMet, as well as the location of four additional cross-links. Only a single peptide, containing Lys465, is covalently coupled to C34, indicating that the recognition site for the anticodon is close to this sequence in the three-dimensional structure of MetRS. The D loop at one corner of the tRNA molecule is cross-linked to three peptides, containing Lys402, Lys439, and Lys596. The 5' terminus of the tRNA is cross-linked to Lys640, near the carboxy terminus of the enzyme. Since the 3' end of tRNAfMet is positioned close to the active site in the N-terminal domain [Hountondji, C., Blanquet, S., & Lederer, F. (1985) Biochemistry 24, 1175-1180], this result indicates that the carboxy ends of the two polypeptide chains of native dimeric MetRS are folded back toward the N-terminal domain of each subunit.

Localization of noncovalently bound ethidium in free and methionyl-tRNA synthetase bound tRNAfMet by singlet-singlet energy transfer

Ethidium binds tRNAfMet with 17-fold enhancement in the emission intensity at 600 nm. Fluorescence titration of tRNAfMet with ethidium indicates a single high-affinity site in tRNAfMet with a dissociation constant of 5 microM. Ethidium is apparently rigidly bound to tRNAfMet and effectively shielded from solvent. tRNAfMet(8-13), tRNAfMet(3'-Flc), and tRNAfMet(D-PF) with fluorophores at thiouridine, the 3'-terminus, and dihydrouridine, respectively, are prepared, and the singlet-singlet energy-transfer efficiencies between these fluorophores and noncovalently bound ethidium are determined. The transfer efficiency between bound ethidium and the fluorophore in tRNAfMet(8-13) determined by donor quenching and sensitized emission is the same, strongly suggesting that there is only one bound ethidium per tRNAfMet molecule. The apparent distances between ethidium and various fluorophores including 3'-fluorescein, the 8-13 photo-cross-link, and D-proflavin are 41, 19, and 30 A, respectively, assuming random orientation between the donor and the acceptor. The results suggest that noncovalently bound ethidium is intercalated in the amino acid acceptor stem. In the complex of tRNAfMet and methionyl-tRNA synthetase, the transfer efficiencies for the tRNAfMet(8-13), tRNAfMet(3'-Flc), and tRNAfMet(D-PF) are reduced, enhanced, and little changed, respectively. These methionyl-tRNA synthetase induced changes suggest changes in the conformation of the 3'-terminal unpaired bases and the relative orientation or location between tRNAfMet and ethidium upon binding of methionyl-tRNA synthetase.

Identification of peptide sequences at the tRNA binding site of Escherichia coli methionyl-tRNA synthetase

Four different structural regions of Escherichia coli tRNAfMet have been covalently coupled to E. coli methionyl-tRNA synthetase (MetRS) by using a tRNA derivative carrying a lysine-reactive cross-linker. We have previously shown that this cross-linking occurs at the tRNA binding site of the enzyme and involves reaction of only a small number of the potentially available lysine residues in the protein [Schulman, L. H., Valenzuela, D., & Pelka, H. (1981) Biochemistry 20, 6018-6023; Valenzuela, D., Leon, O., & Schulman, L. H. (1984) Biochem. Biophys. Res. Commun. 119, 677-684]. In this work, four of the cross-linked peptides have been identified. The tRNA-protein cross-linked complex was digested with trypsin, and the peptides attached to the tRNA were separated from the bulk of the tryptic peptides by anion-exchange chromatography. The tRNA-bound peptides were released by cleavage of the disulfide bond of the cross-linker and separated by reverse-phase high-pressure liquid chromatography, yielding five major peaks. Amino acid analysis indicated that four of these peaks contained single peptides. Sequence analysis showed that the peptides were cross-linked to tRNAfMet through lysine residues 402, 439, 465, and 640 in the primary sequence of MetRS. Binding of the tRNA therefore involves interactions with the carboxyl-terminal half of MetRS, while X-ray crystallographic data have shown the ATP binding site to be located in the N-terminal domain of the protein [Zelwer, C., Risler, J. L., & Brunie, S. (1982) J. Mol. Biol. 155, 63-81].(ABSTRACT TRUNCATED AT 250 WORDS)

Specific sequence homology and three-dimensional structure of an aminoacyl transfer RNA synthetase

Few and limited amino acid sequence homologies have been found among eight bacterial aminoacyl transfer RNA (tRNA) synthetases whose primary structures are known. The entire 939-amino acid primary structure of Escherichia coli isoleucyl-tRNA synthetase is now reported. In a sequence of 11 consecutive amino acids matching a sequence in E. coli methionyl-tRNA synthetase, there are ten identical residues and one conservative change. This is the strongest homology recorded between any two aminoacyl tRNA synthetases. This part of the methionine enzyme's three-dimensional structure has been determined, and it occurs in a mononucleotide binding fold; a close three-dimensional structural homology of this part of the enzyme with Bacillus stearothermophilus tyrosyl-tRNA synthetase has also been reported. The three synthetases probably fold identically in this region.

Structural and functional aspects of domain motions in proteins

Three distinct categories of large-scale flexibility in proteins have been documented by single-crystal X-ray diffraction studies: the relatively free movement of essentially rigid globular domains that are connected by a flexible segment of polypeptide, the reorientation of essentially rigid domains among a few distinct conformations, and the concerted transition of a contiguous region of the surface of a protein from a disordered state to an ordered state. In a number of examples, well-defined functions can be assigned to these large-scale structural changes. The occurrence of such motions in proteins of known structure is reviewed, and the best-studied examples are discussed in detail to allow a critical evaluation of the methods used to identify and study these motions.

Modular arrangement of functional domains along the sequence of an aminoacyl tRNA synthetase

Gene deletions show that much of Escherichia coli alanine tRNA synthetase is dispensable for each of three activities and that these activities appear to require specific domains arranged linearly along the polypeptide. Thus, variable fusions of extra polypeptide domains to a catalytic core may account for the diverse of aminoacyl tRNA synthetases.

The amino acid sequence of the tyrosyl-tRNA synthetase from Bacillus stearothermophilus

The primary structure of the tyrosyl-tRNA synthetase (TyrTS) of Bacillus stearothermophilus has been deduced from the nucleotide sequence of the cloned gene and from the amino acid sequence of peptides isolated from the purified enzyme. TyrTS (B. stearothermophilus) has a molecular weight of 47316 and the sequence is 56% homologous with that of TyrTS (Escherichia coli). The binding domain for the substrate intermediate tyrosyl adenylate is located in the N-terminal portion of the polypeptide and is highly conserved in both enzymes. Several lysine residues, which are shielded from acetylation in the TyrTS-tRNATyr complex, are also located in a stretch of highly conserved sequence.

Primary structure of the Saccharomyces cerevisiae gene for methionyl-tRNA synthetase

The sequence of a 5-kilobase DNA insert containing the structural gene for yeast cytoplasmic methionyl-tRNA synthetase has been determined and a unique open reading frame of 2,253 nucleotides encoding a polypeptide chain of 751 amino acids (Mr, 85,500) has been characterized. The data obtained on the purified enzyme (subunit size, amino acid composition, and COOH-terminal sequence) are consistent with the gene structure. The protein sequence deduced from the nucleotide sequence reveals no obvious internal repeats. This protein sequence shows a high degree of homology with that of Escherichia coli methionyl-tRNA synthetase within a region that forms the putative methionyl adenylate binding site. This strongly suggests that both proteins derive from a common ancestor.

A stereochemical and positional isotope-exchange study of the mechanism of activation of methionine by methionyl-tRNA synthetase from Escherichia coli

Methionyl-tRNA synthetase from Escherichia coli catalyses the activation of [18O2]methionine by adenosine 5'-[(R)-alpha 17O]triphosphate with inversion of configuration at P alpha. Furthermore methionyl-tRNA synthetase does not catalyse positional isotope exchange in adenosine 5'-[beta-18O2]triphosphate in the absence of methionine or in the presence of the competitive inhibitor, methioninol, which eliminates the possibility of either adenylyl-enzyme or adenosine metaphosphate intermediates being involved. These observations require that methionyl-tRNA synthetase catalyses the activation of methionine by an associative 'in-line' nucleotidyl transfer mechanism. A kinetic study of positional isotope exchange in adenosine 5'-[beta-18O2]triphosphate in the presence of methionine, Mg2+ and methionyl-tRNA synthetase showed that torsional equilibration (18O exchange into the P alpha--O--P beta bridge) occurs faster than tumbling (18O exchange into P gamma by rotation about the C2 axis of Mg[18O2]PPi), demonstratings that the positional isotope exchange occurs at least in part in the E X Met-AMP X Mg[18O2]PPi complex.