Recognition of †RNAs by Aminoacyl-†RNA Synthetases

Analysis of sequence dependent variations in secondary and tertiary structure of tRNA molecules

The double helical regions of the five tRNA(Phe) and two tRNA(Asp) crystal structures have been analyzed using the local basepair step parameters. The sequence dependent effects in the mini double helices of tRNA are very similar to those observed in the crystal structures of oligonucleotides in the A-form, the purine-pyrimidine and purine-purine steps have small roll angles when compared to the fiber models of A-DNA as well as A-RNA, while the pyrimidine-purine doublet steps have large roll angles. The orientation of the basepairs in the D-stem is unusual and invariant i.e. they are different from the other three stems but are very similar in all the five tRNA(Phe) crystal structures, presumably due to tertiary interaction of the Watson-Crick basepairs with other bases, with all bases being highly conserved. The origin of the differences between the tertiary structures of tRNA(Phe) and tRNA(Asp) from yeast has also been investigated. It is found that even though the angle between the acceptor arm and the D-stem is very similar in the two structures, the angle subtended by the acceptor arm and the anticodon arm is smaller in the tRNA(Phe) structure (by more than 10 degrees). This is due to differences in the orientation of the two mini helices constituting the anticodon arm, which are inclined to each other by approximately 25 degrees in tRNA(Phe) and 16 degrees in tRNA(Asp). In addition, the acceptor arm, the D-stem and the anticodon stem are nearly coplanar in tRNA(Phe), while in tRNA(Asp) the anticodon stem projects out of the plane defined by the acceptor arm and the anticodon stem. These two features together lead to a larger separation between the acceptor and anticodon ends in tRNA(Asp) and indicate that the junction between the D-stem and the anticodon stem is quite variable, with features characteristic of a ball-and-socket type joint and determined for each tRNA molecule by the base sequence at the junction.

The non-enzymatic specific amino-acylation of transfer RNA at high pressure

This paper shows that the phenylalanine-specific tRNA of Escherichia coli as well as the yellow lupin methionine initiator tRNAMet can be charged specifically with phenylalanine and methionine, respectively, in the absence of specific aminoacyl-tRNA synthetases, under high pressure of a maximum of 6 kbar (1 bar = 10(5) Pa; 1 atm = 1.01 x 10(5) Pa). The esterification reaction takes places at the 3' end of the tRNA molecules. The yield of Phe-tRNAPhe or Met-tRNAMet at high pressure is approximately 10 times lower than that of the enzymatic aminoacylation reaction. This reaction seems to be specific, and mis-aminoacylation of tRNAPhe and tRNAMet with serine is negligible. It is well known that tRNA undergoes conformational changes during interaction with an aminoacyl-tRNA synthetase. Similarly, on the basis of circular dichroism spectra, we showed that the conformation of tRNA at high pressure differs slightly from its original A-RNA form. Therefore, it can be speculated that the chargeable conformation of tRNA induced by the aminoacyl-tRNA synthetase during enzymatic aminoacylation and the one created at high pressure are similar and are most probably formed by a dehydration mechanism. We think that the 'unique' tertiary structure of tRNA existing under high pressure creates an active centre which might itself catalyse ester bond formation. Therefore, the structure of the amino acid stem of tRNA may determine (code) the charging of the particular amino acid to specific tRNA. This code is clearly distinct from the rules of the classical genetic code.

Peptide-chain elongation in eukaryotes

The elongation phase of translation leads to the decoding of the mRNA and the synthesis of the corresponding polypeptide chain. In most eukaryotes, two distinct protein elongation factors (eEF-1 and eEF-2) are required for elongation. Each is active as a complex with GTP. eEF-1 is a multimer and mediates the binding of the cognate aminoacyl-tRNA to the ribosome, while eEF-2, a monomer, catalyses the movement of the ribosome relative to the mRNA. Recent work showing that bacterial ribosomes possess three sites for tRNA binding and that during elongation tRNAs may occupy 'hybrid' sites is incorporated into a model of eukaryotic elongation. In fungi, elongation also requires a third factor, eEF-3. A number of mechanisms exist to promote the accuracy or 'fidelity' of elongation: eEF-3 may play a role here. cDNAs for this and the other elongation factors have been cloned and sequenced, and the structural and functional properties of the elongation factors are discussed. eEF-1 and eEF-2 can be regulated by phosphorylation, and this may serve to control rates of elongation in vivo.

The 2.9 A crystal structure of T. thermophilus seryl-tRNA synthetase complexed with tRNA(Ser)

The crystal structure of Thermus thermophilus seryl-transfer RNA synthetase, a class 2 aminoacyl-tRNA synthetase, complexed with a single tRNA(Ser) molecule was solved at 2.9 A resolution. The structure revealed how insertion of conserved base G20b from the D loop into the core of the tRNA determines the orientation of the long variable arm, which is a characteristic feature of most serine specific tRNAs. On tRNA binding, the antiparallel coiled-coil domain of one subunit of the synthetase makes contacts with the variable arm and T psi C loop of the tRNA and directs the acceptor stem of the tRNA into the active site of the other subunit. Specificity depends principally on recognition of the shape of tRNA(Ser) through backbone contacts and secondarily on sequence specific interactions.

In vivo expression and mitochondrial import of normal and mutated tRNA(thr) in Leishmania

Evidence suggests that mitochondria of protozoans and plants contain nuclear-encoded tRNAs. In trypanosomatids, the entire set of tRNAs in the mitochondria are presumably imported from the nucleus, but the mechanism of tRNA import is not presently understood. In this study, we have employed a plasmid-encoded nuclear tRNA gene as a means of investigating tRNA expression and mitochondrial import in vivo in Leishmania tarentolae. Using a Leishmania plasmid, we cloned a 1-kb or 250-bp restriction fragment carrying the nuclear tRNA(thr) gene and three in vitro mutagenized derivatives: Tac6 (an insertion of 6 nucleotides at the anticodon loop), Td4 (a 4-nt insert at the D-loop) and Tv4 (a 4-nt insert at the variable arm). Leishmania cells stably transfected with these plasmids were then examined for tRNA expression and import by Northern analysis. The results show that the plasmid-encoded wild type tRNA(thr) gene produced a significantly elevated level of expression in the cytosol. Similarly, the Tac6-transfected cells exhibited a large abundance of the mutant RNA relative to the normal tRNA (chromosome-encoded gene transcripts) in the cytosol. Furthermore, the mutant Tac6 RNA was found imported into mitochondria, although the proportion of the mutant vs. normal tRNA in mitochondria was greatly reduced as compared to that in the cytosol. We suggest that the mitochondrial import machinery is capable of discriminating against the mutant RNA in favor of the normal tRNA for import. In another example, we found that the Tv4 gene showed expression, albeit somewhat reduced, but its import into mitochondria was completely blocked. Unexpectedly, the 4-base addition mutation (Td4) at the D-loop showed neither expression nor import. While these results clearly signify the importance of various segments within the tRNA gene for in vivo expression, our data underscore the significance of the variable loop for mitochondrial import. It is our belief that this plasmid-encoded tRNA gene expression system in Leishmania may be useful in gaining further insights on tRNA import.

Initiator transfer RNAs

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The transfer RNA identity problem: a search for rules

Correct recognition of transfer RNAs (tRNAs) by aminoacyl-tRNA synthetases is central to the maintenance of translational fidelity. The hypothesis that synthetases recognize anticodon nucleotides was proposed in 1964 and had considerable experimental support by the mid-1970s. Nevertheless, the idea was not widely accepted until relatively recently in part because the methodologies initially available for examining tRNA recognition proved hampering for adequately testing alternative hypotheses. Implementation of new technologies has led to a reasonably complete picture of how tRNAs are recognized. The anticodon is indeed important for 17 of the 20 Escherichia coli isoaccepting groups. For many of the isoaccepting groups, the acceptor stem or position 73 (or both) is important as well.

Triple aminoacylation specificity of a chimerized transfer RNA

We report here the rational design and construction of a chimerized transfer RNA with tripartite aminoacylation specificity. A yeast aspartic acid specific tRNA was transformed into a highly efficient acceptor of alanine and phenylalanine and a moderate acceptor of valine. The transformation was guided by available knowledge of the requirements for aminoacylation by each of the three amino acids and was achieved by iterative changes in the local sequence context and the structural framework of the variable loop and the two variable regions of the dihydrouridine loop. The changes introduced to confer efficient acceptance of the three amino acids eliminate aminoacylation with aspartate. The interplay of determinants and antideterminants for different specific aminoacylations, and the constraints imposed by the structural framework, suggest that a tRNA with an appreciable capacity for more than three efficient aminoacylations may be inherently difficult to achieve.

The evolutionary change of the genetic code as restricted by the anticodon and identity of transfer RNA

The discovery of non-universal genetic codes in several mitochondria and nuclear systems during the part ten years has necessitated a reconsideration of the concept that the genetic code is universal and frozen, as was once believed. Here, the flexibility of the relationship between codons and amino acids is discussed on the basis of the distribution of non-universal genetic codes in various organisms insofar as has been observed to date. Judging from the result of recent investigations into tRNA identity, it would appear that the non-participation of the anticodon in recognition by aminoacyl-tRNA synthetase has significantly influenced the variability of codons.

Four newly located pseudouridylate residues in Escherichia coli 23S ribosomal RNA are all at the peptidyltransferase center: analysis by the application of a new sequencing technique

A new technique has been developed for the facile location of pseudouridylate (psi) residues in any RNA molecule. The method uses two known modification procedures which in combination uniquely identify U residues which have been converted into psi. The first procedure involves reaction of all U-like and G-like residues with N-cyclohexyl-N'-beta-(4-methylmorpholinium)ethylcarbodiimide p-tosylate (CMC), followed by alkaline removal of all CMC groups except those linked to the N3 of psi. This stops reverse transcription, resulting in a gel band which identifies the U residue. The second procedure is uridine-specific hydrazinolysis which cleaves the RNA chain at all U residues and produces a gel band upon reverse transcription. psi residues, being resistant to hydrazinolysis, are not cleaved and do not stop reverse transcription. This leads to the absence of a band at psi residues. The combined method can also distinguish psi from 5-methyluridine, 4-thiouridine, uridine-5-oxyacetic acid, and 2-thio-5-methylaminomethyluridine as shown by treating rRNA and tRNA species known to contain these modified bases at defined sites. By this procedure, four new sites for psi in Escherichia coli 23S RNA were discovered, and one was disproven. The four new sites are at positions 2457, 2504, 2580, and 2605. The erroneous site is at position 2555. These four new psi residues, which are all in or within 2-3 residues of the peptidyltransferase ring, are thus in a position to play a functional and/or structural role at the peptidyltransferase center.(ABSTRACT TRUNCATED AT 250 WORDS)

Recognition of tRNA(Cys) by Escherichia coli cysteinyl-tRNA synthetase

A study of the recognition of tRNA(Cys) by Escherichia coli cysteinyl-tRNA synthetase using in vivo and in vitro methods was performed. All three anticodon nucleotides, the discriminator nucleotide (73), and some elements within the tertiary domain (the D stem/loop, the T psi C stem/loop, and the variable loop) are important for recognition; the anticodon stem and acceptor stem appear to contain no essential elements. A T7 RNA polymerase transcript corresponding to tRNA(Cys) is only a 5.5-fold worse substrate than native tRNA(Cys) (in terms of the specificity constant, kcat/Km), mainly due to an increase in the value of Km for the transcript. The greatest loss of specificity caused by mutation of a single nucleotide occurs when the discriminator U73 is changed; kcat/Km declines 3-4 orders of magnitude depending on the substitution. Mutations in the wobble nucleotide of the anticodon also cause reductions in the specificity constant of 3 orders of magnitude, while mutations in the other anticodon nucleotides caused lesser effects. Interestingly, a C35A mutation (with the phenylalanine anticodon GAA) had no effect on aminoacylation by the cysteinyl-tRNA synthetase. Several amber suppressor tRNAs were constructed whose in vivo identity did not correlate with their in vitro specificity, indicating the need for both types of experiments to understand the factors which maintain tRNA specificity.

A mitochondrial tRNA anticodon swap associated with a muscle disease

We have identified an unusual mitochondrial (mt) tRNA mutation in a seven year-old girl with a pure myopathy. This G to A transition at mtDNA position 15990 changed the anticodon normally found in proline tRNAs (UGG) to the one found in serine tRNAs (UGA), and is the first pathogenic anticodon alteration described in a higher eukaryote. The mutant mtDNA was heteroplasmic (85% mutant) in muscle but was undetectable in white blood cells from the patient and her mother. Analysis of single muscle fibres indicated that mutant mtDNAs severely impaired mitochondrial protein synthesis and respiratory chain activity, but only when present at greater than 90%. The recessive behaviour of this mtDNA alteration may explain the patient's relatively mild clinical phenotype.

Random-splitting of tRNA transcripts as an approach for studying tRNA-protein interactions

Location of phosphodiester bonds essential for aminoacylation of bovine tRNA(Trp) was identified using a randomly cleaved transcript synthesized in vitro. It was found that cleavage of phosphodiester bonds after nucleotides in positions 21, 22, 36-38, 57-59, 62 and 64 were critical for aminoacylation capacity of tRNA(Trp)-transcript. These cleavage sites were located in the regions of tRNA molecule protected by the cognate synthetase against chemical modification and in the regions presumably outside the contact area as well. These results indicate that for maintenance of aminoacylation ability the intactness of the certain regions of the tRNA backbone structure is necessary. Random splitting of non-modified RNA with alkali followed by separation of active and inactive molecules and identification of cleavage sites developed in this work may become a general approach for studying the role of RNA covalent structure in its interaction with proteins.

Synthesis of homocysteine thiolactone by methionyl-tRNA synthetase in cultured mammalian cells

Homocysteine thiolactone is a product of an error-editing reaction, catalyzed by Escherichia coli and Saccharomyces cerevisiae methionyl-tRNA synthetases, which prevents incorporation of homocysteine into tRNA and protein both in vitro and in vivo. Here, homocysteine thiolactone is also shown to be synthesized by cultured mammalian cells such as human cervical carcinoma (HeLa), mouse renal adenocarcinoma (RAG), and Chinese hamster ovary (CHO) cells labeled with [35S]methionine, but not by normal human and mouse (Balb/c 3T3) fibroblasts. A temperature-sensitive methionyl-tRNA synthetase mutant of CHO cells, Met-1, does not make the thiolactone at the non-permissive temperature. The data indicate that methionyl-tRNA synthase is involved in synthesis of homocysteine thiolactone in CHO cells, thereby extending this important proofreading mechanism to mammalian cells.

Editing of transfer RNAs in Acanthamoeba castellanii mitochondria

With the discovery of RNA editing, a process whereby the primary sequence of RNA is altered after transcription, traditional concepts of genetic information transfer had to be revised. The known RNA editing systems act mainly on messenger RNAs, introducing sequence changes that alter their coding properties. An editing system that acts on transfer RNAs is described here. In the mitochondria of Acanthamoeba castellanii, an amoeboid protozoan, certain transfer RNAs differ in sequence from the genes that encode them. The changes consist of single-nucleotide conversions (U to A, U to G, and A to G) that appear to arise posttranscriptionally, are localized in the acceptor stem, and have the effect of correcting mismatched base pairs. Editing thus restores the base pairing expected of a normal transfer RNA in this region.

Structural aspects and evolutionary implications of the recognition between tRNAs and aminoacyl-tRNA synthetases

Recent structural discoveries in the fields of tRNAs and aminoacyl-tRNA synthetases (aaRS), such as the existence of two classes of aminoacyl tRNA synthetases, the modular character of aaRS with domains homologous to other existing proteins, and the absence of direct interactions between the catalytic site containing the aminoacid binding pocket and the anticodon point the way to an understanding of the origin of the genetic code.

Non-canonical substrates of aminoacyl-tRNA synthetases: the tRNA-like structure of brome mosaic virus genomic RNA

A 3-D model of the tyrosylable tRNA-like domain of the genomic brome mosaic virus RNAs was built by computer modelling based on solution probing of the molecule with different chemical and enzymatic reagents. This model encompasses four major structural domains, including two peculiar substructures oriented perpendicularly and mimicking a tRNA structure, and a fifth domain which makes the connection with the rest of the viral RNA. After recalling the different steps that led to the present structural knowledge of the BMV tRNA-like domain, we review its novel structural features revealed by the modelling and that did not appear in older versions of 3-D models of this structure. These features comprise additional base-pairs, hairpin loops, new tertiary long-range interactions, and a second pseudoknot. The main goal of this paper is to strengthen the validity of the model by establishing correlations between the putative 3-D conformation and the functional properties of the domain. For that, we show how the present structural model rationalises mutagenic and footprinting data that have established the importance of specific regions of the RNA for its recognition and aminoacylation by yeast tyrosyl-tRNA synthetase. We discuss further how the model corroborates mutational analyses performed to understand recognition of this RNA domain by the (ATP,CTP):tRNA nucleotidyl-transferase and by the viral replicase. The published mutants of the BMV tRNA-like domain fall into two classes. In one class, the mutants leave unchanged the overall architecture of the molecule, thereby affecting functions directly. In the second class, the overall architecture of the mutants is perturbed, and thus functions are affected indirectly.

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

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

Yeast aspartyl-tRNA synthetase: a structural view of the aminoacylation reaction

The refinement of the crystal structure of a binary complex formed by yeast AspRS and tRNA(Asp) provided a detailed understanding of the recognition of tRNA by an aminoacyl-tRNA synthetase. The crystal structures of several complexes containing ATP, alone or with aspartic acid, were also determined and refined. These studies led to a complete description of the active site of the enzyme and to the elucidation of the location and interactions of the various substrates. Based on these structural results, a class II-specific pathway for the aminoacylation reaction can be proposed.

Relationship between the structure and function of Escherichia coli initiator tRNA

Through functional studies of mutant tRNAs, we have identified sequence and/or structural features important for specifying the many distinctive properties of E coli initiator tRNA. Many of the mutant tRNAs contain an anticodon sequence change from CAU-->CUA and are now substrates for E coli glutaminyl-tRNA synthetase (GlnRS). We describe here the effect of further mutating the discriminator base 73 and nucleotide 72 at the end of the acceptor stem on: i) recognition of the mutant tRNAs by E coli GlnRS; ii) recognition by E coli methionyl-tRNA transformylase; and iii) activity of the mutant tRNAs in initiation in E coli. For GlnRS recognition, our results are, in general, consistent with interactions found in the crystal structure of the E coli GlnRS-glutamine tRNA complex. The results also support our previous conclusion that formylation of initiator tRNA is important for its function in initiation.

Selectivity and specificity in the recognition of tRNA by E coli glutaminyl-tRNA synthetase

The specific recognition by Escherichia coli glutaminyl-tRNA synthetase (GlnRS) of tRNA(Gln) is mediated by extensive protein:RNA contacts and changes in the conformation of tRNA(Gln) when complexed with GlnRS. In vivo accuracy of aminoacylation depends on two factors: competition between synthetases, and the context and recognition of identity elements in the tRNA. The structure of the tRNA(Gln):GlnRS complex supports studies from amber and opal suppressor tRNAs, complemented by in vitro aminoacylation of the mutated tRNA transcripts, that the glutamine identity elements are located in the anticodon and acceptor stem of tRNA(Gln). Recognition of individual functional groups in tRNA, for example the 2-amino group of guanosine, is also evident from the result with inosine-substituted tRNAs. Communication between anticodon and acceptor stem recognition is indicated by mutants in GlnRS isolated by genetic selection with opal suppressor tRNAs which are altered in interactions with the inside of the L-shaped tRNA. We have also used genetic selection to obtain mutants of GlnRS altered in acceptor stem recognition with relaxed specificity for amber suppressor tRNAs, and a more extensive mutational analysis shows the importance of the acceptor binding domain to accurate recognition of tRNA.

Anticodon-dependent aminoacylation of RNA minisubstrate by lysyl-tRNA synthetase

Specific inhibition of mammalian lysyl-tRNA synthetase by polyU is shown. Inhibition of the enzyme is dependent on the length of the oligonucleotide, since oligoU molecules with a length of less than 8 residues do not inhibit the aminoacylation, whilst the effect of oligoU molecules with a length of about 30 residues is the same as that of polyU. Inhibition is a result of recognition by the enzyme of the tRNALys anticodon sequence (UUU) coded by polyU. Aminoacylation of the oligoU molecule with attached CCA sequence (G(U)20-CCA) by yeast and mammalian lysyl-tRNA synthetases is demonstrated.

Fluorine-19 nuclear magnetic resonance as a probe of the solution structure of mutants of 5-fluorouracil-substituted Escherichia coli valine tRNA

In order to utilize 19F nuclear magnetic resonance (NMR) to probe the solution structure of Escherichia coli tRNAVal labeled by incorporation of 5-fluorouracil, we have assigned its 19F spectrum. We describe here assignments made by examining the spectra of a series of tRNAVal mutants with nucleotide substitutions for individual 5-fluorouracil residues. The result of base replacements on the structure and function of the tRNA are also characterized. Mutants were prepared by oligonucleotide-directed mutagenesis of a cloned tRNAVal gene, and the tRNAs transcribed in vitro by bacteriophage T7 RNA polymerase. By identifying the missing peak in the 19F NMR spectrum of each tRNA variant we were able to assign resonances from fluorouracil residues in loop and stem regions of the tRNA. As a result of the assignment of FU33, FU34 and FU29, temperature-dependent spectral shifts could be attributed to changes in anticodon loop and stem conformation. Observation of a magnesium ion-dependent splitting of the resonance assigned to FU64 suggested that the T-arm of tRNAVal can exist in two conformations in slow exchange on the NMR time scale. Replacement of most 5-fluorouracil residues in loops and stems had little effect on the structure of tRNAVal; few shifts in the 19F NMR spectrum of the mutant tRNAs were noted. However, replacing the FU29.A41 base-pair in the anticodon stem with C29.G41 induced conformational changes in the anticodon loop as well as in the P-10 loop. Effects of nucleotide substitution on aminoacylation were determined by comparing the Vmax and Km values of tRNAVal mutants with those of the wild-type tRNA. Nucleotide substitution at the 3' end of the anticodon (position 36) reduced the aminoacylation efficiency (Vmax/Km) of tRNAVal by three orders of magnitude. Base replacement at the 5' end of the anticodon (position 34) had only a small negative effect on the aminoacylation efficiency. Substitution of the FU29.A41 base-pair increased the Km value 20-fold, while Vmax remained almost unchanged. The FU4.A69 base-pair in the acceptor stem, could readily be replaced with little effect on the aminoacylation efficiency of E. coli tRNAVal, indicating that this base-pair is not an identity element of the tRNA, as suggested by others.

Crucial role of pyrophosphate in the aminoacylation of E. coli tRNA(Phe) by yeast phenylalanyl-tRNA synthetase

Rapid inactivation of the yeast phenylalanyl-tRNA synthetase in the course of aminoacylation of the heterologous E. coli tRNA(Phe) is observed. This inactivation occurs due to the formation of the tight complex of the enzyme with the pyrophosphate formed during the aminoacylation reaction. This complex is shown to be the normal intermediate of the reaction. Possible inactivation mechanism and correlation between structural differences of yeast and E. coli tRNAs(Phe) with the changes in the enzymatic mechanism of aminoacylation are discussed.

Specific valylation of turnip yellow mosaic virus RNA by wheat germ valyl-tRNA synthetase determined by three anticodon loop nucleotides

The valylation by wheat germ valyl-tRNA synthetase of anticodon loop mutants of turnip yellow mosaic virus RNA has been studied. RNA substrates 264 nucleotides long were made by T7 RNA polymerase from cDNA encompassing the 3' tRNA-like region of genomic RNA. Substitution singly, or in combination, of three nucleotides in the anticodon loop resulted in very poor valylation (Vmax/KM less than 10(-3) relative to wild type). These nucleotides thus represent the major valine identity determinants recognized by wheat germ valyl-tRNA synthetase; their relative contribution to valine identity, in descending order, was as follows: the middle nucleotide of the anticodon (A56 in TYMV RNA), the 3' anticodon nucleotide (C55), and the 3'-most anticodon loop nucleotide (C53). Substitutions in the wobble position (C57) had no significant effect on valylation kinetics, while substitutions of the discriminator base (A4) resulted in small decreases in Vmax/Km. Mutations in the major identity nucleotides resulted in large increases in KM, suggesting that wheat germ valyl-tRNA synthetase has a lowered affinity for variant substrates with low valine identity. Comparison with other studies using valyl-tRNA synthetases from Escherichia coli and yeast indicates that the anticodon has been phylogenetically conserved as the dominant valine identity region, while the identity contribution of the discriminator base has been less conserved. The mechanism by which anticodon mutations are discriminated also appears to vary, being affinity-based for the wheat germ enzyme, and kinetically-based for the yeast enzyme [Florentz et al. (1991) Eur. J. Biochem. 195, 229-234].

A new crystal form of the complex between seryl-tRNA synthetase and tRNA(Ser) from Thermus thermophilus that diffracts to 2.8 A resolution

Two distinct complexes between seryl-tRNA synthetase and tRNA(Ser) from Thermus thermophilus have been crystallized using ammonium sulphate as a precipitant. Form III crystals grow from solutions containing a 1:2.5 stoichiometry of synthetase dimer to tRNA. They are of monoclinic space group C2 with unit cell dimensions a = 211.6 A, b = 126.8 A, c = 197.1 A, beta = 132.4 degrees and diffract to about 3.5 A. Preliminary crystallographic results show that the crystallographic asymmetric unit contains two synthetase dimers. Form IV crystals grow from solutions containing a 1:1.5 stoichiometry of synthetase dimer to tRNA. They are of orthorhombic space group P2(1)2(1)2(1) with unit cell dimensions a = 124.5 A, b = 128.9 A, c = 121.2 A and diffract to 2.8 A resolution. Preliminary crystallographic results show that these crystals contain only one tRNA molecule bound to a synthetase dimer.

Experimental studies on the origin of the genetic code and the process of protein synthesis: a review update

This article is an update of our earlier review (Lacey and Mullins, 1983) in this journal on the origin of the genetic code and the process of protein synthesis. It is our intent to discuss only experimental evidence published since then although there is the necessity to mention the old enough to place the new in context. We do not include theoretical nor hypothetical treatments of the code or protein synthesis. Relevant data regarding the evolution of tRNAs and the recognition of tRNAs by aminoacyl-tRNA-synthetases are discussed. Our present belief is that the code arose based on a core of early assignments which were made on a physico-chemical and anticodonic basis and this was expanded with new assignments later. These late assignments do not necessarily show an amino acid-anticodon relatedness. In spite of the fact that most data suggest a code origin based on amino acid-anticodon relationships, some new data suggesting preferential binding of Arg to its codons are discussed. While information regarding coding is not increasing very rapidly, information regarding the basic chemistry of the process of protein synthesis has increased significantly, principally relating to aminoacylation of mono- and polyribonucleotides. Included in those studies are several which show stereoselective reactions of L-amino acids with nucleotides having D-sugars. Hydrophobic interactions definitely play a role in the preferences which have been observed.

Editing of errors in selection of amino acids for protein synthesis

All living cells must conduct protein synthesis with a high degree of accuracy maintained in the transmission and flow of information from gene to finished protein product. One crucial "quality control" point in maintaining a high level of accuracy is the selectivity by which aminoacyl-tRNA synthetases furnish correctly activated amino acids, attached to tRNA species, as the building blocks for growing protein chains. During selection of amino acids, synthetases very often have to distinguish the cognate substrate from a homolog having just one fewer methyl group in its structure. The binding energy of a methyl group is estimated to contribute only a factor of 100 to the specificity of binding, yet synthetases distinguish such closely related amino acids with a discrimination factor of 10,000 to 100,000. Examples of this include methionine versus homocysteine, isoleucine versus valine, alanine versus glycine, and threonine versus serine. Many investigators have demonstrated in vitro the ability of certain aminoacyl-tRNA synthetases to edit, that is, correct or prevent incorrect attachment of amino acids to tRNA molecules. Several major editing pathways are now established from in vitro data. Further, at least some aminoacyl-tRNA synthetases have recently been shown to carry out the editing function in vivo. Editing has been demonstrated to occur in both Escherichia coli and Saccharomyces cerevisiae. Significant energy is expended by the cell for editing of misactivated amino acids, which can be reflected in the growth rate. Because of this, cellular levels of aminoacyl-tRNA synthetases, as well as amino acid biosynthetic pathways which yield competing substrates for protein synthesis, must be carefully regulated to prevent excessive editing. High-level expression of recombinant proteins imposes a strain on the biosynthetic capacity of the cell which frequently results in misincorporation of abnormal or wrong amino acids owing in part to limited editing by synthetases. Unbalanced amino acid pools associated with some genetic disorders in humans may also lead to errors in tRNA aminoacylation. The availability of X-ray crystallographic structures of some synthetases, combined with site-directed mutagenesis, allows insights into molecular details of the extraordinary selectivity of synthetases, including the editing function.

Footprinting evidence for close contacts of the yeast tRNA(Asp) anticodon region with aspartyl-tRNA synthetase

Chemical footprinting experiments on brewer's yeast tRNA(Asp) complexed to its cognate aspartyl-tRNA synthetase are reported: they demonstrate that bases of the anticodon loop, including the anticodon itself, are in close proximity with the synthetase. Contacts were determined using dimethylsulfate as the probe for testing reactivity of guanine and cytosine residues in free and complexed tRNA. Results correlate with the decrease in aspartylation activity of yeast tRNA(Asp) molecules mutated at these contact positions and will be compared with other structural data arising from solution and crystallographic studies on the aspartic acid complex.

Effect of conformational features on the aminoacylation of tRNAs and consequences on the permutation of tRNA specificities

The structure and function of in vitro transcribed tRNA(Asp) variants with inserted conformational features characteristic of yeast tRNA(Phe), such as the length of the variable region or the arrangement of the conserved residues in the D-loop, have been investigated. Although they exhibit significant conformational alterations as revealed by Pb2+ treatment, these variants are still efficiently aspartylated by yeast aspartyl-tRNA synthetase. Thus, this synthetase can accommodate a variety of tRNA conformers. In a second series of variants, the identity determinants of yeast tRNA(Phe) were transplanted into the previous structural variants of tRNA(Asp). The phenylalanine acceptance of these variants improves with increasing the number of structural characteristics of tRNA(Phe), suggesting that phenylalanyl-tRNA synthetase is sensitive to the conformational frame embedding the cognate identity nucleotides. These results contrast with the efficient transplantation of tRNA(Asp) identity elements into yeast tRNA(Phe). This indicates that synthetases respond differently to the detailed conformation of their tRNA substrates. Efficient aminoacylation is not only dependent on the presence of the set of identity nucleotides, but also on a precise conformation of the tRNA.

Identity determinants of E. coli threonine tRNA

To investigate the identity determinants of E. coli threonine tRNA, various transcripts were prepared by in vitro transcription system with T7 RNA polymerase. Substitutions of the anticodon second letter G35 and the third letter U36 to other nucleotides led to a remarkable decrease of threonine charging activity. Charging experiments with a series of anticodon-deletion transcripts also suggest the importance of the G35U36 sequence. A mutation at either the G1-C72 or C2-G71 base pair in the acceptor stem seriously affected the threonine charging activity. These results indicate that the second and third positions of the anticodon and the first and second base pairs in the acceptor stem are the recognition sites of E. coli tRNA(THR) for threonyl-tRNA synthetase. Discriminator base, A73, is not involved in threonine charging activity.