Structural homology in the amino-terminal domains of two aminoacyl-tRNA synthetases

A structure-based multiple sequence alignment of all class I aminoacyl-tRNA synthetases

The superimposable dinucleotide fold domains of MetRS, GlnRS and TyrRS define structurally equivalent amino acids which have been used to constrain the sequence alignments of the 10 class I aminoacyl-tRNA synthetases (aaRS). The conservation of those residues which have been shown to be critical in some aaRS enables to predict their location and function in the other synthetases, particularly: i) a conserved negatively-charged residue which binds the alpha-amino group of the amino acid substrate; ii) conserved residues within the inserted domain bridging the two halves of the dinucleotide-binding fold; and iii) conserved residues in the second half of the fold which bind the amino acid and ATP substrate. The alignments also indicate that the class I synthetases may be partitioned into two subgroups: a) MetRS, IleRS, LeuRS, ValRS, CysRS and ArgRS; b) GlnRS, GluRS, TyrRS and TrpRS.

The aminoacyl-tRNA synthetase family: modules at work

The combined use of molecular and structural biology techniques has proved very efficient in elucidating structure-function relationships in aminoacyl-tRNA synthetases. Our present understanding of this family of enzymes is based on two main unifying principles: (i) division into two different classes, corresponding to two different modes of ATP binding and attachment of the activated amino acid to the last nucleotide of tRNA (either 2'OH or 3'OH of the ribose) by two different catalytic mechanisms and two structural domains with completely different folding, and (ii) the modular organization into separate and additional domains that we are just beginning to understand. Sequence analysis complements very nicely existing structural, biochemical and genetic results and makes them more general, leading to verifiable predictions.

Structural and functional relationships between aminoacyl-tRNA synthetases

Aminoacyl-tRNA synthetases can be divided in two groups of equal size on the basis of differences in the structure of their active sites. The core of class I synthetases is the classical nucleotide-binding domain with its characteristic Rossmann fold. In contrast, the active site of class II synthetases is built around an antiparallel beta-sheet, to which the substrates bind. This classification, which is based on structural data (amino acid sequences and tertiary structures), can be rationalized in functional terms.

Amino acid substrate specificity of Escherichia coli phenylalanyl-tRNA synthetase altered by distinct mutations

Neither the tertiary structure nor the location of active sites are known for phenylalanyl-tRNA synthetase (PheRS; alpha 2 beta 2 structure), a member of class II aminoacyl-tRNA synthetases. In an attempt to detect the phenylalanine (Phe) binding site, two Escherichia coli PheRS mutant strains (pheS), which were resistant to p-fluorophenylalanine (p-F-Phe) were analysed genetically. The pheS mutations were found to cause Ala294 to Ser294 exchanges in the alpha subunits from both independent strains. This alteration (S294) resided in the well-conserved C-terminal part of the alpha subunit, precisely within motif 3, a typical class II tRNA synthetase sequence. We thus propose that motif 3 participates in the formation of the Phe binding site of PheRS. Mutation S294 was also the key for proposing a mechanism by which the substrate analogue p-F-Phe is excluded from the enzymatic reaction; this may be achieved by steric interactions between the para-position of the aromatic ring and the amino acid residue at position 294. The Phe binding site model was then tested by replacing the alanine at position 294 as well as the two flanking phenylalanines (positions 293 and 295) by a number of selected other amino acids. In vivo and in vitro results demonstrated that Phe293 and Phe295 are not directly involved in substrate binding, but replacements of those residues affected PheRS stability. However, exchanges at position 294 altered the binding of Phe, and certain mutants showed pronounced changes in specificity towards Phe analogues. Of particular interest was the Gly294 PheRS in which presumably an enlarged cavity for the para position of the aromatic ring allowed an increased aminoacylation of tRNA with p-F-Phe. Moreover, the larger para-chloro and para-bromo derivatives of Phe could interact with this enzyme in vitro and became highly toxic in vivo. The possible exploitation of the Gly294 mutant PheRS for the incorporation of non-proteinogenic amino acids into proteins 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)

Evolution and relatedness in two aminoacyl-tRNA synthetase families

Sequence segments of about 140 amino acids in length, each containing a selected consensus region, were used in alignments of the aminoacyl-tRNA synthetases with the aim of discerning their evolutionary relationships. In all cases tested, enzymes specific for the same amino acid from a variety of organisms grouped together, reinforcing the supposition that the aminoacyl-tRNA synthetases are very ancient enzymes that evolved to include the full complement of 20 amino acids long before the divergence leading to prokaryotes and eukaryotes. The enzymes are divided into two mutually exclusive groups that appear to have evolved from independent roots. Group I, for which two sequence segments were analyzed, contains the enzymes specific for glutamic acid, glutamine, tryptophan, tyrosine, valine, leucine, isoleucine, methionine, and arginine. Group II enzymes include those activating threonine, proline, serine, lysine, aspartic acid, asparagine, histidine, alanine, glycine, and phenylalanine. Both groups contain a spectrum of amino acid types, suggesting the possibility that each could have once supported an independent system for protein synthesis. Within each group, enzymes specific for chemically similar amino acids tend to cluster together, indicating that a major theme of synthetase evolution involved the adaptation of binding sites to accommodate related amino acids with subsequent specialization to a single amino acid. In a few cases, however, synthetases activating dissimilar amino acids are grouped together.

Cytoplasmic aspartyl-tRNA synthetase from Saccharomyces cerevisiae. Study of its functional organisation by deletion analysis

Aspartyl-tRNA synthetase (AspRS) from yeast, a homodimer of 125 kDa, was shortened by several residues from the C- and N-termini, via site-directed mutagenesis, to examine the contribution of the removed peptides to the enzyme properties. This study showed that the N-terminal sequence up to amino acid 70 (which confers peculiar ionic properties to the protein) is dispensable for activity. Domains located beyond amino acid 70 appeared to have increasing catalytic importance; the removal of 80 or 90 residues affected the Km values for ATP and deletions of 101 or 140 amino acids profoundly modified the physiochemical properties of AspRS, and by consequence, its structural organisation (extraction of the mutated proteins out of the cells required the presence of SDS). On the C-terminal side, very limited modifications readily affected the enzyme properties. Deletion of as few as three residues increased the Km for ATP and reduced the aminoacylation kcat as well as the thermostability of the adenylate synthesis activity; the kcat of this step was impaired after deletion of two further residues. Finally, shortening the C-terminal decapeptide completely inactivated AspRS, whilst affecting neither its affinity for tRNAAsp nor its dimerisation capacity. These data reveal the role of the C-terminal decapeptide as a determinant in both reactions catalysed by AspRS. This peptide is involved in ATP binding, stabilising the functional conformation of the amino-acid-activating domain and probably maintaining the tRNA-acceptor end in a reactive position with regard to the activated amino acid.

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)

Enzymatic aminoacylation of an eight-base-pair microhelix with histidine

The major determinant for the identity of alanine tRNAs is a single base pair in the acceptor helix that is proximal to the site of amino acid attachment. A 7-base-pair microhelix that recreates the acceptor helix can be charged with alanine. No other examples of charging of small helices with specific amino acids have been reported, to our knowledge. We show here that a 13-base-pair and an 8-base-pair hairpin helix that reconstruct a domain and subdomain, respectively, of histidine tRNAs can be charged with histidine. We also show that transplantation of a base pair that is unique to histidine tRNAs is sufficient to consider histidine acceptance on a domain and subdomain of alanine tRNA. Both alanine and histidine aminoacyl-tRNA synthetases retain specificity for their cognate synthetic substrates. Alanine- and histidine-specific microhelices may resemble a system that arose early in the evolution of charging and coding.

Synthetic peptide model of an essential region of an aminoacyl-tRNA synthetase

A 40 amino acid sequence of the unsolved structure of Escherichia coli alanine-tRNA synthetase is essential for tRNA binding and encodes an immunological determinant that cross-reacts with antibodies raised against a eukaryote (insect Bombyx mori) alanine enzyme. The secondary structure of this sequence is predicted to be an amphiphilic alpha-helix that includes one aspartyl and eight glutamyl side chain carboxyl groups. The antibody reactivity and the conformation of a synthetic peptide model of this region (Glu346 to Ser385) were investigated. In addition, double Arg----Gln and Leu----Ala substitutions were separately placed in the enzyme on the hydrophilic and hydrophobic face, respectively, of the predicted helix. These mutations conserve the polar/nonpolar character of each face and retain the potential for helix formation. Circular dichroism spectra of the synthetic peptide model demonstrate the potential for amphiphilic helix formation for the segment from Glu346 to Ser385. The behavior of the mutations in the enzyme, together with earlier data and immunological assays presented here, suggests that one face of the putative helix is an antigenic region of the surface of the enzyme where it contributes to the interaction with alanine tRNA and that the specific sequence of the helix is an important determinant of enzyme stability.

A second class of synthetase structure revealed by X-ray analysis of Escherichia coli seryl-tRNA synthetase at 2.5 A

The three-dimensional crystal structure of seryl-transfer RNA synthetase from Escherichia coli, refined at 2.5 A resolution, is described. It has an N-terminal domain that forms an antiparallel alpha helical coiled-coil, stretching 60 A out into the solvent and stabilized by interhelical hydrophobic interactions and an active-site alpha-beta domain based around a seven-stranded antiparallel beta sheet. Unlike the three other known synthetase structures, the enzyme contains no classical nucleotide-binding fold, and is the first representative of a second class of aminoacyl-tRNA synthetase structures.

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)

Nuclear gene for mitochondrial leucyl-tRNA synthetase of Neurospora crassa: isolation, sequence, chromosomal mapping, and evidence that the leu-5 locus specifies structural information

We have isolated and characterized the nuclear gene for the mitochondrial leucyl-tRNA synthetase (LeuRS) of Neurospora crassa and have established that a defect in this structural gene is responsible for the leu-5 phenotype. We have purified mitochondrial LeuRS protein, determined its N-terminal sequence, and used this sequence information to identify and isolate a full-length genomic DNA clone. The 3.7-kilobase-pair region representing the structural gene and flanking regions has been sequenced. The 5' ends of the mRNA were mapped by S1 nuclease protection, and the 3' ends were determined from the sequence of cDNA clones. The gene contains a single short intron, 60 base pairs long. The methionine-initiated open reading frame specifies a 52-amino-acid mitochondrial targeting sequence followed by a 942-amino-acid protein. Restriction fragment length polymorphism analyses mapped the mitochondrial LeuRS structural gene to linkage group V, exactly where the leu-5 mutation had been mapped before. We show that the leu-5 strain has a defect in the structural gene for mitochondrial LeuRS by restoring growth under restrictive conditions for this strain after transformation with a wild-type copy of the mitochondrial LeuRS gene. We have cloned the mutant allele present in the leu-5 strain and identified the defect as being due to a Thr-to-Pro change in mitochondrial LeuRS. Finally, we have used immunoblotting to show that despite the apparent lack of mitochondrial LeuRS activity in leu-5 extracts, the leu-5 strain contains levels of mitochondrial LeuRS protein to similar to those of the wild-type strain.

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).

Structure of E. coli glutaminyl-tRNA synthetase complexed with tRNA(Gln) and ATP at 2.8 A resolution

The crystal structure of Escherichia coli glutaminyl-tRNA synthetase (GlnRS) complexed with its cognate glutaminyl transfer RNA (tRNA(Gln] and adenosine triphosphate (ATP) has been derived from a 2.8 angstrom resolution electron density map and the known protein and tRNA sequences. The 63.4-kilodalton monomeric enzyme consists of four domains arranged to give an elongated molecule with an axial ratio greater than 3 to 1. Its interactions with the tRNA extend from the anticodon to the acceptor stem along the entire inside of the L of the tRNA. The complexed tRNA retains the overall conformation of the yeast phenylalanine tRNA (tRNA(Phe] with two major differences: the 3' acceptor strand of tRNA(Gln) makes a hairpin turn toward the inside of the L, with the disruption of the final base pair of the acceptor stem, and the anticodon loop adopts a conformation not seen in any of the previously determined tRNA structures. Specific recognition elements identified so far include (i) enzyme contacts with the 2-amino groups of guanine via the tRNA minor groove in the acceptor stem at G2 and G3; (ii) interactions between the enzyme and the anticodon nucleotides; and (iii) the ability of the nucleotides G73 and U1.A72 of the cognate tRNA to assume a conformation stabilized by the protein at a lower free energy cost than noncognate sequences. The central domain of this synthetase binds ATP, glutamine, and the acceptor end of the tRNA as well as making specific interactions with the acceptor stem.2+t is

Nuclear gene for mitochondrial leucyl-tRNA synthetase of Neurospora crassa: isolation, sequence, chromosomal mapping, and evidence that the leu-5 locus specifies structural information

We have isolated and characterized the nuclear gene for the mitochondrial leucyl-tRNA synthetase (LeuRS) of Neurospora crassa and have established that a defect in this structural gene is responsible for the leu-5 phenotype. We have purified mitochondrial LeuRS protein, determined its N-terminal sequence, and used this sequence information to identify and isolate a full-length genomic DNA clone. The 3.7-kilobase-pair region representing the structural gene and flanking regions has been sequenced. The 5' ends of the mRNA were mapped by S1 nuclease protection, and the 3' ends were determined from the sequence of cDNA clones. The gene contains a single short intron, 60 base pairs long. The methionine-initiated open reading frame specifies a 52-amino-acid mitochondrial targeting sequence followed by a 942-amino-acid protein. Restriction fragment length polymorphism analyses mapped the mitochondrial LeuRS structural gene to linkage group V, exactly where the leu-5 mutation had been mapped before. We show that the leu-5 strain has a defect in the structural gene for mitochondrial LeuRS by restoring growth under restrictive conditions for this strain after transformation with a wild-type copy of the mitochondrial LeuRS gene. We have cloned the mutant allele present in the leu-5 strain and identified the defect as being due to a Thr-to-Pro change in mitochondrial LeuRS. Finally, we have used immunoblotting to show that despite the apparent lack of mitochondrial LeuRS activity in leu-5 extracts, the leu-5 strain contains levels of mitochondrial LeuRS protein to similar to those of the wild-type strain.

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.

Structure of tyrosyl-tRNA synthetase refined at 2.3 A resolution. Interaction of the enzyme with the tyrosyl adenylate intermediate

The crystal structure of tyrosyl-tRNA synthetase (EC 6.1.1.1) from Bacillus stearothermophilus has been refined to a crystallographic R-factor of 22.6% at 2.3 A resolution using a restrained least-squares procedure. In the final model the root-mean-square deviation from ideality for bond distances is 0.018 A and for angle distances is 0.044 A. Each monomer consists of three domains: an alpha/beta domain (residues 1 to 220) containing a six-stranded beta-sheet, an alpha-helical domain (248 to 318) containing five helices, and a disordered C-terminal domain (319 to 418) for which the electron density is very weak and where it has not been possible to trace the polypeptide chain. Complexes of the enzyme with the catalytic intermediate tyrosyl adenylate and the inhibitor tyrosinyl adenylate have also been refined to R-factors of 23.9% at 2.8 A resolution and 21.0% at 2.7 A resolution, respectively. Formation of the complexes results in some crystal cracking, but there is no significant difference in the conformation of the polypeptide chain of the three structures described here. The relative orientation of the alpha/beta and alpha-helical domains is similar to that previously observed for the "A" subunit of a deletion mutant lacking the C-terminal domain. Differences between these structures are confined to surface loops that are involved in crystal packing. Tyrosyl adenylate and tyrosinyl adenylate bind in similar conformations within a deep cleft in the alpha/beta domain. The tyrosine moiety is in the equivalent position to that occupied by tyrosine in crystals of the truncated mutant and makes similar strong polar interactions with the enzyme. The alpha-phosphate group interacts with the main-chain nitrogen of Asp38. The two hydroxyl groups of the ribose form strong interactions with the protein. The 2'-hydroxyl group interacts with the carboxylate of Asp194 and the main-chain nitrogen of Gly192 while the 3'-hydroxyl interacts with a tightly bound water molecule (Wat326). The adenine moiety appears to make no significant polar interactions with the protein. The results of site-directed mutagenesis studies are examined in the light of these refined structures.

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.

Study of the arrangement of the functional domains along the yeast cytoplasmic aspartyl-tRNA synthetase

Aspartyl-tRNA synthetase from yeast (AspRS) was screened for functional domains by measuring the effect of two types of amino acid mutations on its catalytic properties: (a) insertion of a dipeptide or a tetrapeptide along the polypeptide chain, (b) deletion of various lengths from the enzyme C-terminal. It was shown that insertion mutations significantly affect the kinetic properties of AspRS only when occurring in the second quarter of the molecule and the two centrally located mutations even inactivate the enzyme completely. Analysis of kinetic data strongly suggests that, in fact, all the observed activity modifications result from alteration of the activation reaction rate constant, kappa cat only. This led to the conclusion that the domain involved in aspartic acid activation should be located in the second quarter of the molecule. Furthermore, a deletion mutant with a modification of the last five amino acid residues was isolated. This mutant is fully active in the activation step, but has lost 80% of the wild-type aminoacylation activity. This involvement of the C-terminus in acylation implies that it has to be folded towards strategic regions of the enzyme, thus favouring conformations required for catalysis or maintaining the tRNA in a functional position.

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.

Characterization of MSM1, the structural gene for yeast mitochondrial methionyl-tRNA synthetase

Respiratory-deficient mutants of Saccharomyces cerevisiae assigned to pet complementation group G72 are impaired in mitochondrial protein synthesis. The loss of this activity has been correlated with the inability of the mutants to acylate the two methionyl-tRNAs of yeast mitochondria. A nuclear gene (MSM1) capable of complementing the respiratory deficiency has been cloned by transformation of the G72 mutant C122/U3 with a yeast genomic library. In situ disruption of the MSM1 gene in a wild-type haploid strain of yeast induces a respiratory-deficient phenotype but does not affect the ability of the mutant to grow on fermentable substrates indicating that the product of MSM1 functions only in mitochondrial protein synthesis. Mitochondrial extracts prepared from the mutant with the disrupted copy of MSM1 were found to be defective in acylation of the two mitochondrial methionyl-tRNAs thereby confirming the identity of MSM1 as the structural gene for the mitochondrial methionyl-tRNA synthetase. The sequence of the protein encoded by MSM1 is similar to the Escherichia coli and yeast cytoplasmic methionyl-tRNA synthetases. Based on the primary-sequence similarities of the three proteins, the mitochondrial enzyme appears to be more related to the bacterial than to the yeast cytoplasmic methionyl-tRNA synthetase.

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.

Properties of N-terminal truncated yeast aspartyl-tRNA synthetase and structural characteristics of the cleaved domain

Cytoplasmic aspartyl-tRNA synthetase from Saccharomyces cerevisiae is a dimer made up of identical subunits of Mr 64,000 as shown by biochemical and crystallographic analyses. Previous studies have emphasized the high sensitivity of the amino-terminal region (residues 1-32) to proteolytic enzymes. This work reports the results of limited tryptic or chymotryptic digestion of the purified enzyme which gives rise to a truncated species that has lost the first 50-64 residues with full retention of both the activity and the dimeric structure. In contrast the larger tryptic fragment is distinguished from the whole enzyme by its weaker retention on heparin-substituted agarose gels. The cleaved N-terminal part presents peculiar structural features, such as a high content in lysine residues arranged in a palindromic fashion. The properties of the trypsin-modified enzyme and of the cleaved amino-terminal region are discussed in relation to the known structural characteristics of aspartyl-tRNA synthetase and of other eukaryotic aminoacyl-tRNA synthetases.

Glycyl-tRNA synthetase of Escherichia coli: immunological homology with phenylalanyl-tRNA synthetase

Antibodies to Escherichia coli glycyl-tRNA synthetase (GlyRS) cross-react extensively with E. coli phenylalanyl-tRNA synthetase (PheRS). These data indicate that structural homology exists between these two enzymes, the only two aminoacyl-tRNA synthetases in E. coli having an alpha 2 beta 2 subunit structure. Although only limited similarities are found in the protein sequences deduced from their known gene sequences, the presence of common epitopes in GlyRS and PheRS adds to a rather long list of physical and chemical similarities between those proteins. In addition, antibodies directed at the alpha- and beta-subunits of GlyRS inhibit both GlyRS and PheRS in the same relative manner, indicating that the function as well as the structure of subunits is similar in each enzyme. In contrast, GlyRS antibodies did not cross-react with a number of other aminoacyl-tRNA synthetase activities from E. coli, yeast, or Bacillus.

Evidence from cassette mutagenesis for a structure-function motif in a protein of unknown structure

The three-dimensional structure of most enzymes is unknown; however, many enzymes may have structural motifs similar to those in the known structures of functionally related enzymes. Evidence is presented that an enzyme of unknown structure [Ile-transfer RNA (tRNA) synthetase] may share a functionally important structural motif with an enzyme of related function (Tyr-tRNA synthetase). This approach involves (i) identifying segments of Ile-tRNA synthetase that have been unusually conserved during evolution, (ii) predicting the function of one such segment by assuming a structural relation between Ile-tRNA synthetase and Tyr-tRNA synthetase, and (iii) testing the predicted function by mutagenesis and subsequent biochemical analysis. Random mutations were introduced by cassette mutagenesis into a ten-amino-acid segment of Ile-tRNA synthetase that was predicted to be involved in the formation of the binding site for isoleucine. Few amino acid substitutions appear to be tolerated in this region. However, one substitution (independently isolated twice) increased the Michaelis constant Km for isoleucine in the adenylate synthesis reaction by greater than 6000-fold, but had little effect on the Km for adenosine triphosphate, the apparent Km for tRNA, or the rate constant kcat.

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.

Isolation, structure and expression of mammalian genes for histidyl-tRNA synthetase

A full length cDNA clone that codes for human histidyl-tRNA synthetase (HRS) and cDNA clones that span the full length transcript of hamster HRS have been isolated. The full length human HRS cDNA was expressed after transfection into Cos 1 cells and a CHO ts mutant defective in the gene for HRS. The complete nucleotide sequence of the hamster and human gene were obtained and extensive homologies were observed in three regions on comparing these sequences between themselves and with the sequence of HRS derived from yeast. These results provide unequivocal evidence that we have indeed cloned the hamster and human gene for HRS. Three overlapping phage recombinants containing the complete hamster chromosomal gene for HRS have also been isolated. The genomic HRS is divided into 13 exons. The precise locations of each of the 5' and 3' exon-intron boundaries were defined by sequencing the appropriate regions of the cloned genomic DNA and aligning them with the sequence of HRS cDNAs. These studies provide the basis for future structural and functional analysis of the gene for HRS. In particular, it will be of interest to examine if different exons of HRS correlate to different domains of the HRS polypeptide.

Polypeptide sequences essential for RNA recognition by an enzyme

Many RNAs are complex, globular molecules formed from elements of secondary and tertiary structure analogous to those found in proteins. Little is known about recognition of RNAs by proteins. In the case of transfer RNAs (tRNAs), considerable evidence suggests that elements dispersed in both the one- and three-dimensional structure are important for recognition by aminoacyl tRNA synthetases. Fragments of alanine tRNA synthetase were created by in vitro manipulations of the cloned alaS gene and examined for their interaction with alanine-specific tRNA. Sequences essential for recognition were located near the middle of the polypeptide, juxtaposed to the carboxyl-terminal side of the domain for aminoacyl adenylate synthesis. The most essential part of the tRNA interaction strength and specificity was dependent on a sequence of fewer than 100 amino acids. Within this sequence, and in the context of the proper conformation, a segment of no more than 17 amino acids was responsible for 25% or more of the total synthetase-tRNA free energy of association. The results raise the possibility that an important part of specific RNA recognition by an aminoacyl tRNA synthetase involves a polypeptide segment that is short relative to the total size of the protein.

Cloning and characterization of the gene coding for cytoplasmic seryl-tRNA synthetase from Saccharomyces cerevisiae

We have screened a Saccharomyces cerevisiae expression library with antibodies against seryl-tRNA synthetase (SerRS) from baker's yeast. In this way we obtained clones which contain serS, the structural gene for seryl-tRNA synthetase. Genomic Southern blots show that the serS gene resides on a 5.0 kb SalI fragment. Nucleotide sequence analysis of the genes revealed a single open reading frame from which we deduced the amino acid sequence of the enzyme consistent with that of two peptides isolated from SerRS. The enzyme is comprised of 462 amino acids consistent with earlier determinations of its molecular weight. The codon usage of serS is typical of abundant yeast proteins. Nuclease S1 analysis of serS mRNA defined the RNA initiation site 20-40 bases downstream from an AT rich sequence containing the TATA box and 21-39 nucleotides upstream of the translation initiation codon. Yeast strains transformed with the cloned gene overproduce seryl-tRNA synthetase in vivo.

Sequence similarities among the family of aminoacyl-tRNA synthetases

Recent affinity labeling studies have led to the identification of lysine residues at the CCA binding site of tRNA in Escherichia coli methionyl- and tyrosyl-tRNA synthetases. The comparison of the labeled peptides to the known primary structures of the aminoacyl-tRNA synthetases reveals new sequence similarities among this family of enzymes. These similarities include a 'constant' lysine residue whose functional significance is discussed. Moreover, a systematic computer analysis was conducted to search for similarities between the aminoacyl-tRNA synthetases taken as pairs.

Potential metal-binding domains in nucleic acid binding proteins

A systematic search for sequences that potentially could form metal-binding domains in proteins has been performed. Five classes of proteins involved in nucleic acid binding or gene regulation were found to contain such sequences. These observations suggest numerous experiments aimed at determining whether metal-binding domains are present in these proteins and, if present, what roles such domains play in the processes of nucleic acid binding and gene regulation.