Crystallographic studies on the aspartyl-tRNA synthetase-tRNAAsp system from yeast. The crystalline aminoacyl-tRNA synthetase

Molecular dynamics simulations of cognate and non-cognate AspRS-tRNAAsp complexes

Aspartyl tRNA synthetase (AspRS), one of the 20 aminoacyl-tRNA synthetases, plays an important role in protein synthesis by catalyzing the aminoacylation reaction and synthesises Aspartyl-tRNA (tRNA^Asp). A typical three-dimensional structure of AspRS comprises three distinct domains for the recognition of cognate tRNA and catalysis, namely, anti-codon binding domain/N-terminal domain, hinge domain and catalytic domain through their interactions with anti-codon loop, D-stem and acceptor arm of cognate tRNA, respectively. In this work, we have studied the structural characteristics of each domain of AspRS to understand the recognition mechanism of tRNA^Asp using molecular dynamics simulations. The dynamics of AspRS-tRNA^Asp complexes from E.coli (cognate and non-cognate), S.cerevisiae (cognate) and T.thermophilus (non-cognate) were compared to understand the differences in recognition of cognate and non-cognate tRNAs. Our results explain that the conformational changes associated with the recognition of tRNA occur only in the cognate complexes. Among the cognate complexes, the conformational changes in yeast AspRS are highly controlled during tRNA^Asp recognition than that of in the E. coli AspRS. Moreover, the functional motions required for the tRNA recognition are observed only in the cognate complexes, and the conformational changes in AspRS and their recognition of tRNA^Asp are organism specific.Communicated by Ramaswamy H. Sarma.

Highlights on trypanosomatid aminoacyl-tRNA synthesis

Aminoacyl-tRNA synthetases aaRSs are responsible for the aminoacylation of tRNAs in the first step of protein synthesis. They comprise a group of enzymes that catalyze the formation of each possible aminoacyl-tRNA necessary for messenger RNA decoding in a cell. These enzymes have been divided into two classes according to structural features of their active sites and, although each class shares a common active site core, they present an assorted array of appended domains that makes them sufficiently diverse among the different living organisms. Here we will explore what is known about the diversity encountered among trypanosomatids' aaRSs that has helped us not only to understand better the biology of these parasites but can be used rationally for the design of drugs against these protozoa.

Thermodynamic characterization of the binding of nucleotides to glycyl-tRNA synthetase

The interaction of adenine nucleotides with glycyl-tRNA synthetase was examined by several experimental approaches. ATP and nonsubstrate ATP analogues render glycyl-tRNA synthetase more resistant to digestion by a number of proteases (thrombin, Arg-C, and chymotrypsin) at concentrations that correlate with their Michaelis constants or inhibition constants, consistent with their exerting an effect by binding at the ATP site. Glycine had little effect alone but potentiated the effect of ATP in increasing the resistance to thrombin digestion, consistent with the formation of an enzyme-bound adenylate. No protection from thrombin digestion was afforded by tRNA(gly). Binding constants were determined by isothermal titration calorimetry at 25 degrees C for ATP (2.5 x 10(5) M(-1)), AMPPNP (3.7 x 10(5) M(-1)), and AMPPCP (2.2 x 10(6) M(-1)). The nucleotides had similar values for DeltaH (-71 kJ mol(-1)), with values for TDeltaS that accounted for the differences in the binding constants. Near-ultraviolet CD spectra of the enzyme-nucleotide complexes indicate that the nucleotides are bound in the anti configuration. A glycyl-adenylate analogue, glycine sulfamoyl adenosine (GSAd), bound with a large value for DeltaH (-187 kJ mol(-1)), which was balanced by a large TDeltaS term to give a binding constant (3.7 x 10(6) M(-1)) only slightly larger than that of AMPPCP. Glycine binding to the enzyme could not be detected calorimetrically, and its presence did not change the thermodynamic parameters for binding of AMPPCP. AMPPNP and AMPPCP were not substrates for glycyl-tRNA synthetase. Analysis of the temperature dependence of ATP binding indicated that the heat capacity change is small, whereas the binding of GSAd is accompanied by a large negative heat capacity change (-2.6 kJ K(-1) mol(-1)). Titrations performed in buffers with different ionization enthalpies indicate that the large value for DeltaH for the adenylate analogue does not arise from a coupled protonation event. Differential scanning calorimetry indicated that glycyl-tRNA synthetase is stabilized by nucleotides. Unfolding of the protein is irreversible, and thermodynamic parameters for unfolding could therefore not be determined. The results are consistent with a significant conformational transition in glycyl-tRNA synthetase coupled to the binding of GSAd.

The free yeast aspartyl-tRNA synthetase differs from the tRNA(Asp)-complexed enzyme by structural changes in the catalytic site, hinge region, and anticodon-binding domain

Aminoacyl-tRNA synthetases catalyze the specific charging of amino acid residues on tRNAs. Accurate recognition of a tRNA by its synthetase is achieved through sequence and structural signalling. It has been shown that tRNAs undergo large conformational changes upon binding to enzymes, but little is known about the conformational rearrangements in tRNA-bound synthetases. To address this issue the crystal structure of the dimeric class II aspartyl-tRNA synthetase (AspRS) from yeast was solved in its free form and compared to that of the protein associated to the cognate tRNA(Asp). The use of an enzyme truncated in N terminus improved the crystal quality and allowed us to solve and refine the structure of free AspRS at 2.3 A resolution. For the first time, snapshots are available for the different macromolecular states belonging to the same tRNA aminoacylation system, comprising the free forms for tRNA and enzyme, and their complex. Overall, the synthetase is less affected by the association than the tRNA, although significant local changes occur. They concern a rotation of the anticodon binding domain and a movement in the hinge region which connects the anticodon binding and active-site domains in the AspRS subunit. The most dramatic differences are observed in two evolutionary conserved loops. Both are in the neighborhood of the catalytic site and are of importance for ligand binding. The combination of this structural analysis with mutagenesis and enzymology data points to a tRNA binding process that starts by a recognition event between the tRNA anticodon loop and the synthetase anticodon binding module.

An example of non-conservation of oligomeric structure in prokaryotic aminoacyl-tRNA synthetases. Biochemical and structural properties of glycyl-tRNA synthetase from Thermus thermophilus

Glycyl-tRNA synthetase (Gly-tRNA synthetase) from Thermus thermophilus was purified to homogeneity and with high yield using a five-step purification procedure in amounts sufficient to solve its crystallographic structure [Logan, D.T., Mazauric, M.-H., Kern, D. & Moras, D. (1995) EMBO J. 14, 4156-4167]. Molecular-mass determinations of the native and denatured protein indicate an oligomeric structure of the alpha 2 type consistent with that found for eukaryotic Gly-tRNA synthetases (yeast and Bombyx mori), but different from that of Gly-tRNA synthetases from mesophilic prokaryotes (Escherichia coli and Bacillus brevis) which are alpha 2 beta 2 tetramers. N-terminal sequencing of the polypeptide chain reveals significant identity, reaching 50% with those of the eukaryotic enzymes (B. mori, Homo sapiens, yeast and Caenorhabditis elegans) but no significant identity was found with both alpha and beta chains of the prokaryotic enzymes (E. coli, Haemophilus influenzae and Coxiella burnetii) albeit the enzyme is deprived of the N-terminal extension characterizing eukaryotic synthetases. Thus, the thermophilic Gly-tRNA synthetase combines strong structural homologies of eukaryotic Gly-tRNA synthetases with a feature of prokaryotic synthetases. Heat-stability measurements show that this synthetase keeps its ATP-PPi exchange and aminoacylation activities up to 70 degrees C. Glycyladenylate strongly protects the enzyme against thermal inactivation at higher temperatures. Unexpectedly, tRNA(Gly) does not induce protection. Cross-aminoacylations reveal that the thermophilic Gly-tRNA synthetase charges heterologous E. coli tRNA(gly(GCC)) and tRNA(Gly(GCC)) and yeast tRNA(Gly(GCC)) as efficiently as T. thermophilus tRNA(Gly). All these aminoacylation reactions are characterized by similar activation energies as deduced from Arrhenius plots. Therefore, contrary to the E. coli and H. sapiens Gly-tRNA synthetases, the prokaryotic thermophilic enzyme does not possess a strict species specificity. The results are discussed in the context of the three-dimensional structure of the synthetase and in the view of the particular evolution of the glycinylation systems.

Role of dimerization in yeast aspartyl-tRNA synthetase and importance of the class II invariant proline

Cytoplasmic aspartyl-tRNA synthetase (AspRS; EC 6.1.1.12) from yeast is, as are most class II synthetases, an alpha 2 dimer. The only invariant amino acid in signature motif 1 of this class is Pro-273; this residue is located at the dimer interface. To understand the role of Pro-273 in the conserved dimeric configuration, we tested the effect of a Pro-273-->Gly (P273G) substitution on the catalytic properties of homo- and heterodimeric AspRS. Heterodimers of AspRS were produced in vivo by overexpression of their respective subunit variants from plasmid-encoded genes and purified to homogeneity in one HPLC step. The homodimer containing the P273G shows an 80% inactivation of the enzyme and an affinity decrease for its cognate tRNA(Asp) of one order of magnitude. The P273G-mutated subunit recovered wild-type enzymatic properties when associated with a native subunit or a monomer otherwise inactivated having an intact dimeric interface domain. These results, which can be explained by the crystal structure of the native enzyme complexed with its substrates, confirm the structural importance of Pro-273 for dimerization and clearly establish the functional interdependence of the AspRS subunits. More generally, the dimeric conformation may be a structural prerequisite for the activity of mononucleotide binding sites constructed from antiparallel beta strands.

Class II aminoacyl transfer RNA synthetases: crystal structure of yeast aspartyl-tRNA synthetase complexed with tRNA(Asp)

The crystal structure of the binary complex tRNA(Asp)-aspartyl tRNA synthetase from yeast was solved with the use of multiple isomorphous replacement to 3 angstrom resolution. The dimeric synthetase, a member of class II aminoacyl tRNA synthetases (aaRS's) exhibits the characteristic signature motifs conserved in eight aaRS's. These three sequence motifs are contained in the catalytic site domain, built around an antiparallel beta sheet, and flanked by three alpha helices that form the pocket in which adenosine triphosphate (ATP) and the CCA end of tRNA bind. The tRNA(Asp) molecule approaches the synthetase from the variable loop side. The two major contact areas are with the acceptor end and the anticodon stem and loop. In both sites the protein interacts with the tRNA from the major groove side. The correlation between aaRS class II and the initial site of aminoacylation at 3'-OH can be explained by the structure. The molecular association leads to the following features: (i) the backbone of the GCCA single-stranded portion of the acceptor end exhibits a regular helical conformation; (ii) the loop between residues 320 and 342 in motif 2 interacts with the acceptor stem in the major groove and is in contact with the discriminator base G and the first base pair UA; and (iii) the anticodon loop undergoes a large conformational change in order to bind the protein. The conformation of the tRNA molecule in the complex is dictated more by the interaction with the protein than by its own sequence.

The three cysteine residues of cytoplasmic aspartyl-tRNA synthetase from Saccharomyces cerevisiae are not essential for its activity

Cytoplasmic aspartyl-tRNA synthetase from Saccharomyces cerevisiae is a dimer made up of identical subunits (Mr 63,000) each of these containing three cysteines (residues 255, 512 and 519 in the amino acid sequence). Thiol-specific probes were used to label these cysteines and study the resulting effect of the modification on the kinetic parameters of both the ATP/PPi exchange and tRNA aminoacylation reactions. Using the classical techniques of protein chemistry it was shown that none of the three cysteines was labelled with iodoacetic acid, whilst N-ethylmaleimide and 5,5'-dithiobis(2-nitrobenzoate) reacted with Cys512 and Cys255, respectively. Only the latter modification was accompanied by a decrease in the rates of both enzyme activities whilst the Km values for the various substrates remained unaffected. Site-directed mutagenesis was also used to replace each of the three cysteines by other residues, either individually or simultaneously. For these experiments the enzyme was expressed in Escherichia coli using an expression vector bearing the structural gene in which the first 13 codons were replaced by the first 14 of the CII lambda gene. The resulting substitution in the amino-terminal part of the expressed enzyme had no effect on the kinetic parameters, compared to those of the enzyme purified from S. cerevisiae. Taking into account the consequences of such substitutions, as well as those of chemical modifications on the two reactions catalysed by the enzyme. ATP/PPi exchange and tRNA aminoacylation, it could be concluded that none of these three cysteines plays any essential role in either substrate binding or catalysis.

Isolation and characterization of the gene coding for Escherichia coli arginyl-tRNA synthetase

The gene coding for Escherichia coli arginyl-tRNA synthetase (argS) was isolated as a fragment of 2.4 kb after analysis and subcloning of recombinant plasmids from the Clarke and Carbon library. The clone bearing the gene overproduces arginyl-tRNA synthetase by a factor 100. This means that the enzyme represents more than 20% of the cellular total protein content. Sequencing revealed that the fragment contains a unique open reading frame of 1734 bp flanked at its 5' and 3' ends respectively by 247 bp and 397 bp. The length of the corresponding protein (577 aa) is well consistent with earlier Mr determination (about 70 kd). Primer extension analysis of the ArgRS mRNA by reverse transcriptase, located its 5' end respectively at 8 and 30 nucleotides downstream of a TATA and a TTGAC like element (CTGAC) and 60 nucleotides upstream of the unusual translation initiation codon GUG; nuclease S1 analysis located the 3'-end at 48 bp downstream of the translation termination codon. argS has a codon usage pattern typical for highly expressed E. coli genes. With the exception of the presence of a HVGH sequence similar to the HIGH consensus element, ArgRS has no relevant sequence homologies with other aminoacyl-tRNA synthetases.

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.

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.

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

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

The microheterogeneity of the crystallizable yeast cytoplasmic aspartyl-tRNA synthetase

Yeast aspartyl-tRNA synthetase is a dimeric enzyme (alpha 2, Mr 125,000) which can be crystallized either alone or complexed with tRNAAsp. When analyzed by electrophoretic methods, the pure enzyme presents structural heterogeneities even when recovered from crystals. Up to three enzyme populations could be identified by polyacrylamide gel electrophoresis and more than ten by isoelectric focusing. They have similar molecular masses and mainly differ in their charge. All are fully active. This microheterogeneity is also revealed by ion-exchange chromatography and chromatofocusing. Several levels of heterogeneity have been defined. A first type, which is reversible, is linked to redox effects and/or to conformational states of the protein. A second one, revealed by immunological methods, is generated by partial and differential proteolysis occurring during enzyme purification from yeast cells harvested in growth phase. As demonstrated by end-group analysis, the fragmentation concerns exclusively the N-terminal end of the enzyme. The main cleavage points are Gln-19, Val-20 and Gly-26. Six minor cuts are observed between positions 14 and 33. The present data are discussed in the perspective of the crystallographic studies on aspartyl-tRNA synthetase.

Cloning and characterization of the gene for Escherichia coli seryl-tRNA synthetase

Seryl-tRNA synthetase is the gene product of the serS locus in Escherichia coli. Its gene has been cloned by complementation of a serS temperature sensitive mutant K28 with an E. coli gene bank DNA. The resulting clones overexpress seryl-tRNA synthetase by a factor greater than 50 and more than 6% of the total cellular protein corresponds to the enzyme. The DNA sequence of the complete coding region and the 5'- and 3' untranslated regions was determined. Protein sequence comparison of SerRS with all available aminoacyl-tRNA synthetase sequences revealed some regions of significant homology particularly with the isoleucyl- and phenylalanyl-tRNA synthetases from E. coli.

Crystals of seryl-tRNA synthetase from Escherichia coli. Preliminary crystallographic data

Crystals of seryl-tRNA synthetase from Escherichia coli can be grown from ammonium sulphate/octyl glucoside solutions in two days. The crystals appear to be very suitable for X-ray analysis, diffracting to at least 2.8 A resolution and being resistant to radiation damage. The crystals are monoclinic (space group C2) with cell parameters a = 148.2 A, b = 90.6 A, c = 69.5 A and beta = 119.0 degrees. Depending on whether the asymmetric unit is the enzyme monomer (Mr 48,414) or dimer the Vm value would be either 4.12 or 2.10 A3/dalton. Although the former would indicate a rather high solvent content, other proteins crystallized in the presence of octyl glucoside have Vm values similar to this.

Nucleotide sequence of the gene coding for yeast cytoplasmic aspartyl-tRNA synthetase (APS); mapping of the 5' and 3' termini of AspRS mRNA

A 3.8 Kb DNA fragment, which contains the structural gene of aspartyl-tRNA synthetase (AspRS) and its flanking regions, has been fully sequenced by the combined M13/dideoxy chain terminator method. From the single open reading frame of correct length (1671 bp) we deduced an amino acid sequence consistent with that of several peptides of AspRS. No significant internal sequence repeats were observed in the primary structure of the protein. The AspRS gene (APS) has a codon usage pattern typical of non abundant proteins. S1 nuclease analysis of APS mRNA showed a major start 17 bases downstream from a "TATA box" and stops near an RNA polymerase terminator sequence.

Leucyl-tRNA and lysyl-tRNA synthetases, derived from the high-Mr complex of sheep liver, are hydrophobic proteins

The leucyl-tRNA and lysyl-tRNA synthetase components of the multienzyme complex from sheep liver were selectively dissociated by hydrophobic interaction chromatography on hexyl-agarose and purified to homogeneity. Conservation of activities during the purification required the presence of Triton X-100. The homogeneous enzymes corresponded to a monomer of Mr 129000 and a dimer of Mr 2 X 79000, respectively. Both were strongly adsorbed to the hydrophobic support phenyl-Sepharose, in conditions where the corresponding purified enzymes from yeast and Escherichia coli were not bound. Moreover, like the corresponding enzymes from yeast but unlike those of prokaryotic origin, the purified leucyl-tRNA and lysyl-tRNA synthetases derived from the complex displayed affinity for polyanionic supports. It is shown that proteolytic conversion of lysyl-tRNA synthetase to a fully active dimer of Mr 2 X 64000, leads to loss of both the hydrophobic and the polyanion-binding properties. These results support the view that each subunit of lysyl-tRNA synthetase is composed of a major catalytic domain, similar in size to the subunit of the prokaryotic enzyme, contiguous to a chain extension which carries both cationic charges and hydrophobic residues. The implications of these findings on the structural organization of the complex are discussed in relation to its other known properties.

Yeast tRNAAsp tertiary structure in solution and areas of interaction of the tRNA with aspartyl-tRNA synthetase. A comparative study of the yeast phenylalanine system by phosphate alkylation experiments with ethylnitrosourea

Ethylnitrosourea is an alkylating reagent preferentially modifying phosphate groups in nucleic acids. It was used to monitor the tertiary structure, in solution, of yeast tRNAAsp and to determine those phosphate groups in contact with the cognate aspartyl-tRNA synthetase. Experiments involve 3' or 5'-end-labelled tRNA molecules, low yield modification of the free or complexed nucleic acid and specific splitting at the modified phosphate groups. The resulting end-labelled oligonucleotides are resolved on polyacrylamide sequencing gels and data analysed by autoradiography and densitometry. Experiments were conducted in parallel on yeast tRNAAsp and on tRNAPhe. In that way it was possible to compare the solution structure of two elongator tRNAs and to interpret the modification data using the known crystal structures of both tRNAs. Mapping of the phosphates in free tRNAAsp and tRNAPhe allowed the detection of differential reactivities for phosphates 8, 18, 19, 20, 22, 23, 24 and 49: phosphates 18, 19, 23, 24 and 49 are more reactive in tRNAAsp, while phosphates 8, 20 and 22 are more reactive in tRNAPhe. All other phosphates display similar reactivities in both tRNAs, in particular phosphate 60 in the T-loop, which is strongly protected. Most of these data are explained by the crystal structures of the tRNAs. Thermal transitions in tRNAAsp could be followed by chemical modifications of phosphates. Results indicate that the D-arm is more flexible than the T-loop. The phosphates in yeast tRNAAsp in contact with aspartyl-tRNA synthetase are essentially contained in three continuous stretches, including those at the corner of the amino acid accepting and D-arm, at the 5' side of the acceptor stem and in the variable loop. When represented in the three-dimensional structure of the tRNAAsp, it clearly appears that one side of the L-shaped tRNA molecule, that comprising the variable loop, is in contact with aspartyl-tRNA synthetase. In yeast tRNAPhe interacting with phenylalanyl-tRNA synthetase, the distribution of protected phosphates is different, although phosphates in the anticodon stem and variable loop are involved in both systems. With tRNAPhe, the data cannot be accommodated by the interaction model found for tRNAAsp, but they are consistent with the diagonal side model proposed by Rich & Schimmel (1977). The existence of different interaction schemes between tRNAs and aminoacyl-tRNA synthetases, correlated with the oligomeric structure of the enzyme, is proposed.

Anticodon-anticodon interactions in solution. Studies of the self-association of yeast or Escherichia coli tRNAAsp and of their interactions with Escherichia coli tRNAVal

The temperature-jump method was used to measure the thermodynamic and kinetic parameters of the yeast tRNAAsp (anticodon GUC) duplex, which involves a U/U mismatch in the middle position of the quasi self-complementary anticodon, and of the yeast tRNAAsp (GUC)-Escherichia coli tRNAVal (GAC) complex, in which the tRNAs have complementary anticodons. The existence of the tRNAAsp duplex involving GUC-GUC interactions as evidenced in the crystal structure has now been demonstrated in solution. However, the value of its association constant (Kass = 10(4)M-1 at 0 degrees C) is characteristic of a rather weak complex, when compared with that between tRNAAsp and tRNAVal (Kass = 4 X 10(6) M-1 at 0 degrees C), the effect being essentially linked to differences in the rate constant for dissociation. tRNAAsp split in the anticodon by T1 ribonuclease gives no relaxation signal, indicating that the effects observed with intact tRNA were entirely due to anticodon interactions. No duplex formation was observed with other tRNAs having quasi self-complementary GNC anticodons (where N is C, A or G), such as E. coli tRNAGly (GCC), E. coli tRNAVal (GAC) or E. coli tRNAAla (GGC). This is compatible with the idea that, probably as in the crystal structure, a short double helix is formed in solution between the two GUC anticodons. Because of steric effects, such a complex formation would be hindered if a cytosine, adenine or guanine residue were located in the middle position of the anticodon. Escherichia coli tRNAAsp possessing a modified G residue, the Q base, at the first position of the anticodon, showed a weaker self-association than yeast tRNAAsp but its complex with E. coli tRNAVal was found to be only 1.5 times less stable than that between yeast tRNAAsp and E. coli tRNAVal. Temperature-jump experiments conducted under conditions mimicking those used for the crystallization of yeast tRNAAsp (in the presence of 1.6 M-ammonium sulphate and 3mM-spermine) revealed an important stabilization of the yeast and E. coli tRNAAsp duplexes or of their complexes with E. coli tRNAVal. The effect is due exclusively to ammonium sulphate; it is entropy driven and its influence is reflected on the association rate constant; no influence on the dissociation rate constant was observed. For all tRNA-tRNA complexes, the melting temperature upon addition of ammonium sulphate was considerably increased. This study permits the definition of solution conditions in which tRNAs with appropriate anticodons exist mainly as anticodon-anticodon dimers.

Crystallographic refinement of yeast aspartic acid transfer RNA

The structure of yeast transfer RNA aspartic acid has been refined in one crystal form to 3 A resolution using the restrained least-squares method of Hendrickson and Konnert and real-space fitting using the FRODO program of Jones. The final crystallographic discrepancy index R is 23.5% for 4585 reflections with magnitudes twice their standard deviations between 10 and 3 A. With lower occupancies for some residues of the D-loop, the phosphate U1, and the base U33, the R-factor is 22.3%. The adaptation of the restrained least-squares program for nucleic acids and the progress of the refinement are described. The conformations are analysed with respect to stereochemistry and folding of the backbone. The contacts and hydrogen bonds of the secondary structure are compared with those of yeast tRNAPhe. The presence of only four bases in the variable loop, instead of five as in yeast tRNAPhe, leads to a rotation of residue 48 and a lateral movement of residue 46. These two rearrangements induce different environments for [U8 . . . A14] . . . A21 as well as for A9 and G45. Otherwise, all tertiary contacts observed in yeast tRNAPhe are present in yeast tRNAAsp, except for the absence of hydrogen-bonding between G18 of the D-loop and C56 of the T-loop. The presence of anticodon triplet pairing leads to a distribution of temperature factors different from that observed in yeast tRNAPhe with a stabilization of the AC stem-and-loop and a destabilization of the T and D-loops. We are inclined to suggest that the labilization of the interactions between the T and D-loops is a consequence of the interaction of the anticodon triplets of symmetry-related molecules through hydrogen bonding, which mimics the interaction between the anticodon and its cognate codon on the messenger RNA.

High-performance liquid chromatographic analysis of crystals of tRNA, aminoacyl-tRNA synthetase, and their complex

High-performance liquid chromatography on an ion exchanger column was successfully used for a rapid biochemical analysis of crystals of yeast tRNAAsp and aspartyl-tRNA synthetase as well as cocrystals formed by the synthetase and the tRNA.

Hydrodynamic properties and structure of the rat liver 12 S arginyl- and lysyl-tRNA synthetase complex

Eukaryotic aminoacyl-tRNA synthetases occur in multienzyme complexes in contrast to their prokaryotic counterparts. A core 12 S rat liver complex (Mr 290,000) was recently purified to homogeneity consisting of two polypeptides with Mr 73,000 and 65,000 identified as lysyl- and arginyl-tRNA synthetase, respectively (Dang et al. (1982) Biochemistry 21,1959-1966). Using the modified hydrodynamic theory of Kirkwood (Kirkwood, J.R. (1954) J. Polym. Sci. 12,1-14), we have determined that the model most consistent with the hydrodynamic properties of the 12 S complex is a tetrameric tetrahedral model.

Large scale purification and structural properties of yeast aspartyl-tRNA synthetase

A large scale purification procedure of baker's yeast aspartyl-tRNA synthetase is described which yields more than 200 mg pure protein starting from 30 Kg of wet commercial cells. The synthetase is an alpha 2 dimer of Mr = 125,000 +/- 5,000 which can be crystallized (J. Mol. Biol. 138, 1980, 129-135). The enzyme has an elongated shape with a Stokes radius of 50 A and a frictional ratio of 1.5. The synthetase has a tendency to aggregate but methods are described where this effect is overcome.

Glycosylation of yeast aspartyl-tRNA synthetase. Affinity labelling by glucose and glucose 6-phosphate

Several lines of evidence establish that the crystallizable aspartyl-tRNA synthetase from Baker's yeast contains some covalently bound glucose: (i) a positive staining of the enzyme was obtained after polyacrylamide gel electrophoresis followed by the concanavalin A-peroxidase test which is specific for glucose and mannose containing proteins; (ii) thin-layer chromatography and gas-liquid chromatography revealed the presence of glucose in enzyme hydrolysates; (iii) immunoaffinoelectrophoresis in agarose gels containing concanavalin A and antibodies raised against aspartyl-tRNA synthetase showed that the enzyme was able to precipitate entirely in the lectin. Finally incubation of the enzyme with [14C]glucose or [14C]glucose 6-phosphate led to the incorporation of radioactivity into trichloroacetic acid-precipitable protein. Indeed immunoprecipitation of [14C]glucose-labelled aspartyl-tRNA synthetase with specific antibodies using the rocket method followed by autoradiography gave a radioactive peak. This last result also demonstrates the possibility of in vitro glycosylation of yeast aspartyl-tRNA synthetase.

Yeast tRNAAsp-aspartyl-tRNA synthetase: the crystalline complex

Aspartyl-tRNA synthetase from yeast, a dimer of molecular weight 125,000 and its cognate tRNA (Mr = 24,160) were co-crystallized using ammonium sulfate as precipitant agent. The presence in the crystals of both components in the two-to-one stoichiometric ratio was demonstrated by electrophoresis, biological activity assays and crystallographic data. Crystals belong to the cubic space group I432 with cell parameter of 354 A and one complex particle per asymmetric unit. The solvent content of about 78% is favorable for a low resolution structural investigation. By exchanging H2O for D2O in mother liquors, advantage can be taken from contrast variation techniques with neutron radiations. Diffraction data to 20 A resolution were measured at five different contrasts, two of them being close to the theoretical matching point of RNA and protein in the presence of ammonium sulfate. The experimental extinction of the diffracted signal was observed to be close to 36% D2O, significantly different from the predicted value of 41%. The phenomenon can be explained by the existence of a large interface region between the two tRNAs and the enzyme. These parts of the molecules are hidden from the solvent and their protons are less easily exchangeable. Accessibility studies toward chemicals of tRNAAsp in solution and in the presence of synthetase are in agreement with such a model.

Isoelectric focusing and isoelectric points of aminoacyl-tRNA synthetases

Isoelectric points and isoelectric focusing behaviour of 10 highly purified eukaryotic aminoacyl-tRNA synthetases from 3 sources, Saccharomyces cerevisiae, Euglena gracilis and Phaseolus vulgaris were examined. The pI-values measured on polyacrylamide gels under native conditions are situated between pH 5.0-7.5. A microheterogeneity was observed for 9 enzymes appearing otherwise homogeneous on gel electrophoresis. A compilation of the isoelectric points of aminoacyl-tRNA synthetases is given and literature data are compared with our experimental results.

Interaction of tRNAPhe and tRNAVal with aminoacyl-tRNA synthetases. A chemical modification study

The alkylation by ethylnitrosourea of phosphodiester bonds in tRNAPhe from yeast and in tRNAVal from yeast and from rabbit liver and that by 4-(N-2-chloroethyl-N-methylamino)-benzylamine of N-7 atoms of guanosine residues in yeast tRNAVal have been used to study the interaction of these tRNAs with aminoacyl-tRNA synthetases. The modifications occurring at low yield were carried out on 3' and/or 5' end-labelled tRNAs either free or in the presence of cognate or non-cognate synthetases. After splitting of the tRNAs at the alkylated positions, the position of the modification sites in the tRNA sequences were detected by acrylamide gel electrophoresis. It was found that the synthetases protect against alkylation certain phosphate or guanosine residues in their cognate tRNAs. Non-cognate synthetases failed to protect efficiently specific positions in tRNA against modification. In yeast tRNAPhe the cognate phenylalanyl-tRNA synthetase protects certain phosphates located in all four stems and in the anticodon and extra-loop of the tRNA. Particularly strong protections occur on phosphate 34 in the anticodon loop and on phosphates 23, 27, 28, 41 and 46 in the D and anticodon stems. In yeast tRNAVal complexed with yeast valyl-tRNA synthetase the protected phosphates are essentially located in the corner between the amino-acid-accepting and D stems, in the D loop, anticodon stem and in the variable region of the tRNA. Three guanosine residues, located in the D stem, and another one in the 3' part of the anticodon stem were also found protected by the synthetase. In mammalian tRNAVal, complexed with the cognate but heterologous yeast valyl-tRNA synthetase, the protected phosphates lie in the anticodon stem, in the extra-loop and in the T psi arm. The location of the protected residues in the structure of three tRNAs suggests some common features in the binding of tRNAs to aminoacyl-tRNA synthetases. These results will be discussed in the light of informations on interaction sites obtained by nuclease digestion and ultraviolet cross-linking methods.

Reversed-phase liquid chromatography of peptides for direct micro-sequencing

Tryptic and cyanogen bromide peptides derived from yeast aspartyl-tRNA synthetase and from Escherichia coli ribosomal proteins were separated by reversed-phase liquid chromatography, employing volatile buffers of low ionic strength. The conditions used allow the performance of micro-sequencing without desalting or extensive lyophilization, and can therefore be applied to peptide mixtures containing hydrophobic fragments which tend to precipitate. To prevent losses of peptides, direct ultra-violet detection of the peptides was preferred, to detection by post-column derivatization with an additional stream splitting device. Preparative separations were performed with 5-10 nmol of peptide mixture; analytical runs were made with 5-10 micrograms of protein hydrolysate.

Covalent attachment of aspartic acid to yeast aspartyl-tRNA synthetase induced by the enzyme

Aspartic acid can be covalently linked to yeast aspartyl-tRNA synthetase and to other proteins, in the absence of tRNA, under conditions where the synthetase activates the amino acid into aspartyl-adenylate, i.e., in the presence of ATP and MgCl2. The linkage between aspartic acid and the protein is acid and alkali resistant; thus it is likely a peptide-like amide bond formed between the activated carboxylate group of aspartic acid and the primary amine function of the side chain of lysine residues.

Formation of a catalytically active complex between tRNAAsp and aspartyl-tRNA synthetase from yeast in high concentrations of ammonium sulphate

The interactions of yeast tRNAAsp with cognate aspartyl-tRNA synthetase have been studied in high concentrations of either sodium chloride or ammonium sulphate by fluorescence titration and small-angle neutron scattering. In solutions containing more than 1M NaCl no complex is formed and enzymatic activity is abolished. In strong contrast, however, the physical measurements showed the formation of a two-to-one tRNA-enzyme complex, with high affinity, in 1.6 M (NH4)2SO4. Aminoacylation assays under the same salt conditions showed the enzymatic fixation of aspartic acid to tRNAAsp to occur at an appreciable rate. The present study emphasizes that the effects of salts on protein-nucleic acid interactions do not depend only on ionic strength but also on the nature of the salt. This study has allowed a rational approach to the crystallisation of a functional tRNAAsp-aspartyl-tRNA synthetase complex (Giegé, Lorber, Ebel, Thierry and Moras (1980) C.R. Acad. Sci. Paris, série D, 291, 393-396).