Involvement of the size and sequence of the anticodon loop in tRNA recognition by mammalian and E. coli methionyl-tRNA synthetases

Solid-Phase-Supported Chemoenzymatic Synthesis of a Light-Activatable tRNA Derivative

Herein, we present a multi‐cycle chemoenzymatic synthesis of modified RNA with simplified solid‐phase handling to overcome size limitations of RNA synthesis. It combines the advantages of classical chemical solid‐phase synthesis and enzymatic synthesis using magnetic streptavidin beads and biotinylated RNA. Successful introduction of light‐controllable RNA nucleotides into the tRNA^Met sequence was confirmed by gel electrophoresis and mass spectrometry. The methods tolerate modifications in the RNA phosphodiester backbone and allow introductions of photocaged and photoswitchable nucleotides as well as photocleavable strand breaks and fluorophores.

Structural and functional insights into Archaeoglobus fulgidus m2G10 tRNA methyltransferase Trm11 and its Trm112 activator

tRNAs play a central role during the translation process and are heavily post-transcriptionally modified to ensure optimal and faithful mRNA decoding. These epitranscriptomics marks are added by largely conserved proteins and defects in the function of some of these enzymes are responsible for neurodevelopmental disorders and cancers. Here, we focus on the Trm11 enzyme, which forms N2-methylguanosine (m2G) at position 10 of several tRNAs in both archaea and eukaryotes. While eukaryotic Trm11 enzyme is only active as a complex with Trm112, an allosteric activator of methyltransferases modifying factors (RNAs and proteins) involved in mRNA translation, former studies have shown that some archaeal Trm11 proteins are active on their own. As these studies were performed on Trm11 enzymes originating from archaeal organisms lacking TRM112 gene, we have characterized Trm11 (AfTrm11) from the Archaeoglobus fulgidus archaeon, which genome encodes for a Trm112 protein (AfTrm112). We show that AfTrm11 interacts directly with AfTrm112 similarly to eukaryotic enzymes and that although AfTrm11 is active as a single protein, its enzymatic activity is strongly enhanced by AfTrm112. We finally describe the first crystal structures of the AfTrm11-Trm112 complex and of Trm11, alone or bound to the methyltransferase inhibitor sinefungin.

Structural basis of the interaction between cyclodipeptide synthases and aminoacylated tRNA substrates

Cyclodipeptide synthases (CDPSs) catalyze the synthesis of various cyclodipeptides by using two aminoacyl-tRNA (aa-tRNA) substrates in a sequential mechanism. Here, we studied binding of phenylalanyl-tRNAPhe to the CDPS from Candidatus Glomeribacter gigasporarum (Cglo-CDPS) by gel filtration and electrophoretic mobility shift assay. We determined the crystal structure of the Cglo-CDPS:Phe-tRNAPhe complex to 5 Å resolution and further studied it in solution using small-angle X-ray scattering (SAXS). The data show that the major groove of the acceptor stem of the aa-tRNA interacts with the enzyme through the basic β2 and β7 strands of CDPSs belonging to the XYP subfamily. A bending of the CCA extremity enables the amino acid moiety to be positioned in the P1 pocket while the terminal A76 adenosine occupies the P2 pocket. Such a positioning indicates that the present structure illustrates the binding of the first aa-tRNA. In cells, CDPSs and the elongation factor EF-Tu share aminoacylated tRNAs as substrates. The present study shows that CDPSs and EF-Tu interact with opposite sides of tRNA. This may explain how CDPSs hijack aa-tRNAs from canonical ribosomal protein synthesis.

Mutations in MARS identified in a specific type of pulmonary alveolar proteinosis alter methionyl-tRNA synthetase activity

Biallelic missense mutations in MARS are responsible for rare but severe cases of pulmonary alveolar proteinosis (PAP) prevalent on the island of La Réunion. MARS encodes cytosolic methionyl-tRNA synthetase (MetRS), an essential translation factor. The multisystemic effects observed in patients with this form of PAP are consistent with a loss-of-function defect in an ubiquitously expressed enzyme. The pathophysiological mechanisms involved in MARS-related PAP are currently unknown. In this work, we analyzed the effect of the PAP-related mutations in MARS on the thermal stability and on the catalytic parameters of the MetRS mutants, relative to wild-type. The effect of these mutations on the structural integrity of the enzyme as a member of the cytosolic multisynthetase complex was also investigated. Our results establish that the PAP-related substitutions in MetRS impact the tRNA^Met -aminoacylation reaction especially at the level of methionine recognition, and suggest a direct link between the loss of activity of the enzyme and the pathological disorders in PAP.

Association of human mitochondrial lysyl-tRNA synthetase with HIV-1 GagPol does not require other viral proteins

In human, the cytoplasmic (cLysRS) and mitochondrial (mLysRS) species of lysyl-tRNA synthetase are encoded by a single gene. Following HIV-1 infection, mLysRS is selectively taken up into viral particles along with the three tRNA^Lys isoacceptors. The GagPol polyprotein precursor is involved in this process. With the aim to reconstitute in vitro the HIV-1 tRNA₃^Lys packaging complex, we first searched for the putative involvement of another viral protein in the selective viral hijacking of mLysRS only. After screening all the viral proteins, we observed that Vpr and Rev have the potential to interact with mLysRS, but that this association does not take place at the level of the assembly of mLysRS into the packaging complex. We also show that tRNA₃^Lys can form a ternary complex with the two purified proteins mLysRS and the Pol domain of GagPol, which mimicks its packaging complex.

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HIV-1 Rev and Vpr proteins have the capacity to bind human mitochondrial LysRS.

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In the complex between HIV-1 Pol and mitochondrial LysRS, Rev and Vpr are excluded.

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Association of Pol with mLysRS recapitulates the tRNA₃^Lys packaging complex of HIV-1.

New method for the orthogonal labeling and purification of Toxoplasma gondii proteins while inside the host cell

Toxoplasma gondii is an obligate intracellular protozoan parasite that is capable of causing severe disease in immunocompromised humans. How T. gondii is able to modulate the host cell to support itself is still poorly understood. Knowledge pertaining to the host-parasite interaction could be bolstered by developing a system to specifically label parasite proteins while the parasite grows inside the host cell. For this purpose, we have created a strain of T. gondii that expresses a mutant Escherichia coli methionyl-tRNA synthetase (MetRS^NLL) that allows methionine tRNA to be loaded with the azide-containing methionine analog azidonorleucine (Anl). Anl-containing proteins are susceptible to a copper-catalyzed “click” reaction to attach affinity tags for purification or fluorescent tags for visualization. The MetRS^NLL-Anl system labels nascent T. gondii proteins in an orthogonal fashion, labeling proteins only in MetRS^NLL-expressing parasites. This system should be useful for nonradioactive pulse-chase studies and purification of nascently translated proteins. Although this approach allows labeling of a diverse array of parasite proteins, secreted parasite proteins appear to be only minimally labeled in MetRS^NLL-expressing T. gondii. The minimal labeling of secreted proteins is likely a consequence of the selective charging of the initiator tRNA (and not the elongator methionine tRNA) by the heterologously expressed bacterial MetRS.

Studying how T. gondii modifies the host cell to permit its survival is complicated by the complex protein environment of the host cell. The approach presented in this article provides the first method for specific labeling of T. gondii proteins while the parasite grows inside the host cell. We show that this approach is useful for pulse-chase labeling of parasite proteins during in vitro growth. It should also be applicable during in vivo infections and in other apicomplexan parasites, including Plasmodium spp.

Mutant methionyl-tRNA synthetase from bacteria enables site-selective N-terminal labeling of proteins expressed in mammalian cells

Newly synthesized cellular proteins can be tagged with a variety of metabolic labels that distinguish them from preexisting proteins and allow them to be identified and tracked. Many such labels are incorporated into proteins via the endogenous cellular machinery and can be used in numerous cell types and organisms. Though broad applicability has advantages, we aimed to develop a strategy to restrict protein labeling to specified mammalian cells that express a transgene. Here we report that heterologous expression of a mutant methionyl-tRNA synthetase from Escherichia coli permits incorporation of azidonorleucine (Anl) into proteins made in mammalian (HEK293) cells. Anl is incorporated site-selectively at N-terminal positions (in competition with initiator methionines) and is not found at internal sites. Site selectivity is enabled by the fact that the bacterial synthetase aminoacylates mammalian initiator tRNA, but not elongator tRNA. N-terminally labeled proteins can be selectively conjugated to a variety of useful probes; here we demonstrate use of this system in enrichment and visualization of proteins made during various stages of the cell cycle. N-terminal incorporation of Anl may also be used to engineer modified proteins for therapeutic and other applications.

Mapping hidden potential identity elements by computing the average discriminating power of individual tRNA positions

The recently published discrete mathematical method, extended consensus partition (ECP), identifies nucleotide types at each position that are strictly absent from a given sequence set, while occur in other sets. These are defined as discriminating elements (DEs). In this study using the ECP approach, we mapped potential hidden identity elements that discriminate the 20 different tRNA identities. We filtered the tDNA data set for the obligatory presence of well-established tRNA features, and then separately for each identity set, the presence of already experimentally identified strictly present identity elements. The analysis was performed on the three kingdoms of life. We determined the number of DE, e.g. the number of sets discriminated by the given position, for each tRNA position of each tRNA identity set. Then, from the positional DE numbers obtained from the 380 pairwise comparisons of the 20 identity sets, we calculated the average excluding value (AEV) for each tRNA position. The AEV provides a measure on the overall discriminating power of each position. Using a statistical analysis, we show that positional AEVs correlate with the number of already identified identity elements. Positions having high AEV but lacking published identity elements predict hitherto undiscovered tRNA identity elements.

Protection-based assays to measure aminoacyl-tRNA binding to translation initiation factors

To decipher the mechanisms of translation initiation, the stability of the complexes between tRNA and initiation factors has to be evaluated in a routine manner. A convenient method to measure the parameters of binding of an aminoacyl-tRNA to an initiation factor results from the property that, when specifically complexed to a protein, the aminoacyl-tRNA often resists spontaneous deacylation. This chapter describes the preparation of suitable aminoacyl-tRNA ligands and their use in evaluating the stability of their complexes with various initiation factors, such as e/aIF2 and e/aIF5B. The advantages and the limitations of the method are discussed.

Translational nonsense codon suppression as indicator for functional pre-tRNA splicing in transformed Arabidopsis hypocotyl-derived calli

The transient expression of three novel plant amber suppressors derived from a cloned Nicotiana tRNA(Ser)(CGA), an Arabidopsis intron-containing tRNA(Tyr)(GTA) and an Arabidopsis intron-containing tRNA(Met)(CAT) gene, respectively, was studied in a homologous plant system that utilized the Agro bacterium-mediated gene transfer to Arabidopsis hypocotyl explants. This versatile system allows the detection of beta-glucuronidase (GUS) activity by histochemical and enzymatic analyses. The activity of the suppressors was demonstrated by the ability to suppress a premature amber codon in a modified GUS gene. Co-transformation of Arabidopsis hypocotyls with the amber suppressor tRNA(Ser) gene and the GUS reporter gene resulted in approximately 10% of the GUS activity found in the same tissue transformed solely with the functional control GUS gene. Amber suppressor tRNAs derived from intron-containing tRNA(Tyr) or tRNA(Met) genes were functional in vivo only after some additional gene manipulations. The G3:C70 base pair in the acceptor stem of tRNA(Met)(CUA) had to be converted to a G3:U70 base pair, which is the major determinant for alanine tRNA identity. The inability of amber suppressor tRNA(Tyr) to show any activity in vivo predominantly results from a distorted intron secondary structure of the corresponding pre-tRNA that could be cured by a single nucleotide exchange in the intervening sequence. The improved amber suppressors tRNA(Tyr) and tRNA(Met) were subsequently employed for studying various aspects of the plant-specific mechanism of pre-tRNA splicing as well as for demonstrating the influence of intron-dependent base modifications on suppressor activity.

Functional dissection of the eukaryotic-specific tRNA-interacting factor of lysyl-tRNA synthetase

In the cytoplasm of higher eukaryotic cells, aminoacyl-tRNA synthetases (aaRSs) have polypeptide chain extensions appended to conventional prokaryotic-like synthetase domains. The supplementary domains, referred to as tRNA-interacting factors (tIFs), provide the core synthetases with potent tRNA-binding capacities, a functional requirement related to the low concentration of free tRNA prevailing in the cytoplasm of eukaryotic cells. Lysyl-tRNA synthetase is a component of the multi-tRNA synthetase complex. It exhibits a lysine-rich N-terminal polypeptide extension that increases its catalytic efficiency. The functional characterization of this new type of tRNA-interacting factor has been conducted. Here we describe the systematic substitution of the 13 lysine or arginine residues located within the general RNA-binding domain of hamster LysRS made of 70 residues. Our data show that three lysine and one arginine residues are major building blocks of the tRNA-binding site. Their mutation into alanine led to a reduced affinity for tRNA(3)(Lys) or minimalized tRNA mimicking the acceptor-TPsiC stem-loop of tRNA(3)(Lys) and a decrease in catalytic efficiency similar to that observed after a complete deletion of the N-terminal domain. Moreover, covalent continuity between the tRNA-binding and core domain is a prerequisite for providing LysRS with a tRNA binding capacity. Thus, our results suggest that the ability of LysRS to promote tRNA(Lys) networking during translation or to convey tRNA(3)(Lys) into the human immunodeficiency virus type 1 viral particles rests on the addition in evolution of this tRNA-interacting factor.

Human tyrosyl-tRNA synthetase shares amino acid sequence homology with a putative cytokine

To test the hypothesis that tRNATyr recognition differs between bacterial and human tyrosyl-tRNA synthetases, we sequenced several clones identified as human tyrosyl-tRNA synthetase cDNAs by the Human Genome Project. We found that human tyrosyl-tRNA synthetase is composed of three domains: 1) an amino-terminal Rossmann fold domain that is responsible for formation of the activated E.Tyr-AMP intermediate and is conserved among bacteria, archeae, and eukaryotes; 2) a tRNA anticodon recognition domain that has not been conserved between bacteria and eukaryotes; and 3) a carboxyl-terminal domain that is unique to the human tyrosyl-tRNA synthetase and whose primary structure is 49% identical to the putative human cytokine endothelial monocyte-activating protein II, 50% identical to the carboxyl-terminal domain of methionyl-tRNA synthetase from Caenorhabditis elegans, and 43% identical to the carboxyl-terminal domain of Arc1p from Saccharomyces cerevisiae. The first two domains of the human tyrosyl-tRNA synthetase are 52, 36, and 16% identical to tyrosyl-tRNA synthetases from S. cerevisiae, Methanococcus jannaschii, and Bacillus stearothermophilus, respectively. Nine of fifteen amino acids known to be involved in the formation of the tyrosyl-adenylate complex in B. stearothermophilus are conserved across all of the organisms, whereas amino acids involved in the recognition of tRNATyr are not conserved. Kinetic analyses of recombinant human and B. stearothermophilus tyrosyl-tRNA synthetases expressed in Escherichia coli indicate that human tyrosyl-tRNA synthetase aminoacylates human but not B. stearothermophilus tRNATyr, and vice versa, supporting the original hypothesis. It is proposed that like endothelial monocyte-activating protein II and the carboxyl-terminal domain of Arc1p, the carboxyl-terminal domain of human tyrosyl-tRNA synthetase evolved from gene duplication of the carboxyl-terminal domain of methionyl-tRNA synthetase and may direct tRNA to the active site of the enzyme.

Identity elements of Thermus thermophilus tRNA(Thr)

In this study, we identified nucleotides that specify aminoacylation of tRNA(Thr) by Thermus thermophilus threonyl-tRNA synthetase (ThrRS) using in vitro transcripts. Mutation studies showed that the first base pair in the acceptor stem as well as the second and third positions of the anticodon are major identity elements of T. thermophilus tRNA(Thr), which are essentially the same as those of Escherichia coli tRNA(Thr). The discriminator base, U73, also contributed to the specific aminoacylation, but not the second base pair in the acceptor stem. These findings are in contrast to E. coli tRNA(Thr), where the second base pair is required for threonylation, with the discriminator base, A73, playing no roles. In addition, among several mutations at the third base pair in the acceptor stem, only the G3-U70 mutant was a poor substrate for ThrRS, suggesting that the G3-U70 wobble pair, which is the identity determinant of tRNA(Ala), acts as a negative element for ThrRS. Similar results were obtained in E. coli and yeast. Thus, this manner of rejection of tRNA(Ala) is also likely to have been retained in the threonine system throughout evolution.

Aspartate identity of transfer RNAs

Structure/function relationships accounting for specific tRNA charging by class II aspartyl-tRNA synthetases from Saccharomyces cerevisiae, Escherichia coli and Thermus thermophilus are reviewed. Effects directly linked to tRNA features are emphasized and aspects about synthetase contribution in expression of tRNA(Asp) identity are also covered. Major identity nucleotides conferring aspartate specificity to yeast, E coli and T thermophilus tRNAs comprise G34, U35, C36, C38 and G73, a set of nucleotides conserved in tRNA(Asp) molecules of other biological origin. Aspartate specificity can be enhanced by negative discrimination preventing, eg mischarging of native yeast tRNA(Asp by yeast arginyl-tRNA synthetase. In the yeast system crystallography shows that identity nucleotides are in contact with identity amino acids located in the catalytic and anticodon binding domains of the synthetase. Specificity of RNA/protein interaction involves a conformational change of the tRNA that optimizes the H-bonding potential of the identity signals on both partners of the complex. Mutation of identity nucleotides leads to decreased aspartylation efficiencies accompanied by a loss of specific H-bonds and an altered adaptation of tRNA on the synthetase. Species-specific characteristics of aspartate systems are the number, location and nature of minor identity signals. These features and the structural variations in aspartate tRNAs and synthetases are correlated with mechanistic differences in the aminoacylation reactions catalyzed by the various aspartyl-tRNA synthetases. The reality of the aspartate identity set is verified by its functional expression in a variety of RNA frameworks. Inversely a number of identities can be expressed within a tRNA(Asp) framework. From this emerged the concept of the RNA structural frameworks underlying expression of identities which is illustrated with data obtained with engineered tRNAs. Efficient aspartylation of minihelices is explained by the primordial role of G73. From this and other considerations it is suggested that aspartate identity appeared early in the history of tRNA aminoacylation systems.

Yeast tRNA(Met) recognition by methionyl-tRNA synthetase requires determinants from the primary, secondary and tertiary structure: a review

The primordial role of the CAU anticodon in methionine identity of the tRNA has been established by others nearly a decade ago in Escherichia coli and yeast tRNA(Met). We show here that the CAU triplet alone is unable to confer methionine acceptance to a tRNA. This requires the contribution of the discriminatory base A73 and the non-anticodon bases of the anticodon loop. To better understand the functional communication between the anticodon and the active site, we analysed the binding and aminoacylation of tRNA(Met) based anticodon and acceptor-stem minihelices and of tRNA(Met) chimeras where the central core region of yeast tRNA(Met) is replaced by that of unusual mitochondrial forms lacking either a D-stem or a T-stem. These studies suggest that the high selectivity of the anticodon bases in tRNA(Met) implies the L-conformation of the tRNA and the presence of a D-stem. The importance of a L-structure for recognition of tRNA(Met) was also deduced from mutations of tertiary interactions known to play a general role in tRNA(Met) folding.

Identity elements of human tRNA(Leu): structural requirements for converting human tRNA(Ser) into a leucine acceptor in vitro

We have previously shown that the exchange of the discriminator base A73 of human tRNA(Leu) for G is alone sufficient to achieve complete loss of leucine acceptance and to create an efficient serine acceptor. The reverse identity switch, however, which was studied using T7 RNA polymerase transcripts of in vitro mutagenized tRNA genes, reveals a far more complex pattern of identity elements for tRNA(Leu). Introduction of the following tRNA(Leu)-specific structures is necessary to transform human tRNA(Ser) into an efficient leucine acceptor: the discriminator base A73, the base pairs C3:G70, A4:U69 and G5:C68 of the acceptor stem, C20a of the DHU loop and the long extra arm. In contrast to tRNA(Ser), human tRNA(Leu) identity requires both the sequence and the correct orientation of the long extra arm, whereas only its orientation is essential for serine identity.

Identity elements of tRNA(Thr) towards Saccharomyces cerevisiae threonyl-tRNA synthetase

Identity elements of tRNA(Thr) towards Saccharomyces cerevisiae threonyl-tRNA synthetase were examined using in vitro transcripts. By mutation studies, a marked decrease in aminoacylation with threonine showed that the first base pair in the acceptor stem and the second and third positions of the anticodon are major identity elements of tRNA(Thr), which are essentially the same as those of Escherichia coli tRNA(Thr). Base substitution of the discriminator base, A73, by G73 or C73 impaired the threonine accepting activity, but not that by U73, suggesting that this position contributes to discrimination from other tRNAs possessing G73 or C73. No effects on aminoacylation were observed with substitutions at the second base pair in the acceptor stem. These are in contrast to E.coli tRNA(Thr) where the second base pair is required for the specific aminoacylation, with the discriminator base playing no roles. Of several mutations at the third base pair in the acceptor stem, only the G3-U70 mutation impaired the activity, suggesting that the G3-U70 wobble pair, the identity determinant of tRNAAla, acts as a negative element for threonyl-tRNA synthetase. These findings indicate that while the first base pair in the acceptor stem and the anticodon nucleotides have been retained as major recognition sites between S. cerevisiae and E.coli tRNA(Thr), the mechanism by which the synthetase recognizes the vicinity of the top of the acceptor stem seems to have diverged with the species.

Maturation of pre-tRNA(fMet) by Escherichia coli RNase P is specified by a guanosine of the 5'-flanking sequence

The C+1/A+72 base pair at the top of the acceptor stem of Escherichia coli tRNA(fMet) accounts for several of the specialized roles of this tRNA in translation initiation. According to the rules of RNA substrate recognition by RNase P, the C+1/A+72 pair is likely to disfavor the 5'-maturation of pre-tRNA(fMet). Indeed, in contrast to other E. coli tRNA species, tRNA(fMet) was not properly matured when overproduced from a multicopy expression vector. Half of the recovered tRNA(fMet) retained an extension at the 5' side. Such a defect of tRNA(fMet) processing could be cured by changing bases C+1 and A+72 by a Watson-Crick base pair or by non-paired bases, provided one of them was a G. It could also be compensated by either (i) over-expression of RNase P or (ii) introduction within the plasmid of one out of the three 5'-flanking sequences naturally occurring in the four E. coli tRNA(fMet) genes. The effect of these flanking sequences on the maturation of tRNA(fMet) could be accounted for by the presence of a G located 2 bases upstream from C+1. Notably, this G is the only residue that is conserved in the 5'-flanking sequences of all four E. coli tRNA(fMet) genes.

Role of the 1-72 base pair in tRNAs for the activity of Escherichia coli peptidyl-tRNA hydrolase

Previous work by Schulman and Pelka (1975) J. Biol. Chem. 250, 542-547, indicated that the absence of a pairing between the bases 1 and 72 in initiator tRNA(fMet) explained the relatively small activity of peptidyl-tRNA hydrolase towards N-acetyl-methionyl-tRNA(fMet). In the present study, the structural requirements for the sensitivity of an N-acetyl-aminoacyl-tRNA to Escherichia coli peptidyl-tRNA hydrolase activity have been further investigated. Ten derivatives of tRNA(fMet) with various combinations of bases at positions 1 and 72 in the acceptor stem have been produced, aminoacylated and chemically acetylated. The release of the aminoacyl moiety from these tRNA derivatives was assayed in the presence of peptidyl-tRNA hydrolase purified from an overproducing strain. tRNA(fMet) derivatives with either C1A72, C1C72, U1G72, U1C72 or A1C72 behaved as poor substrates of the enzyme, as compared to those with C1G72, U1A72, G1C72, A1U72 or G1U72. With the exception of U1G72, it could be therefore concluded that the relative resistance of tRNA(fMet) to peptidyl-tRNA hydrolase did not depend on a particular combination of nucleotides at positions 1 and 72, but rather reflected the absence of a base pairing at these positions. In a second series of experiments, the unpairing of the 1 and 72 bases, created with C-A or A-C bases, instead of G-C in methionyl-tRNA(mMet) or in valyl-tRNA(Val1), was shown to markedly decrease the rate of hydrolysis catalysed by peptidyl-tRNA hydrolase. Altogether, the data indicate that the stability of the 1-72 pair governs the degree of sensitivity of a peptidyl-tRNA to peptidyl-tRNA hydrolase.

Importance of formylability and anticodon stem sequence to give a tRNA(Met) an initiator identity in Escherichia coli

In bacteria, the free amino group of the methionylated initiator tRNA is specifically modified by the addition of a formyl group. The functional relevance of such a formylation for the initiation of translation is not yet precisely understood. Advantage was taken here of the availability of the fmt gene, encoding the Escherichia coli Met-tRNA(fMet) formyltransferase, to measure the influence of variations in the level of formyltransferase activity on the involvement of various mutant tRNA(fMet) and tRNA(mMet) species in either initiation or elongation in vivo. The data obtained established that formylation plays a dual role, firstly, by dictating tRNA(fMet) to engage in the initiation of translation, and secondly, by preventing the misappropriation of this tRNA by the elongation apparatus. The importance of formylation in the initiator identity of tRNA(fMet) was further shown by the demonstration that elongator tRNA(fMet) may be used in initiation and no longer in elongation, provided that it is mutated into a formylatable species and is given the three G.C base pairs characteristic of the anticodon stem of initiator tRNAs.

Escherichia coli tRNA(Asp) recognition mechanism differing from that of the yeast system

Various tRNA transcripts were constructed to study the identity elements of Escherichia coli tRNA(Asp). Base substitutions from G34 to U34 at the first position of the anticodon, and from U35 to A35 at the second, severely impaired the aspartate charging activity. The activity was also decreased, but in a more moderate fashion, by base changes at G2-C71, C36 and C38. Identity nucleotides of tRNA(Asp) are distributed in a different fashion between E. coli and yeast, which occur at the second base pair of the acceptor stem, G10-U25 base pair in the D-stem and 3' half of the anticodon loop.