Discrimination between initiation and elongation of protein biosynthesis in yeast: identity assured by a nucleotide modification in the initiator tRNA

RNA modifying enzymes shape tRNA biogenesis and function

Transfer RNAs (tRNAs) are the most highly modified cellular RNAs, both with respect to the proportion of nucleotides that are modified within the tRNA sequence and with respect to the extraordinary diversity in tRNA modification chemistry. However, the functions of many different tRNA modifications are only beginning to emerge. tRNAs have two general clusters of modifications. The first cluster is within the anticodon stem-loop including several modifications essential for protein translation. The second cluster of modifications is within the tRNA elbow, and roles for these modifications are less clear. In general, tRNA elbow modifications are typically not essential for cell growth, but nonetheless several tRNA elbow modifications have been highly conserved throughout all domains of life. In addition to forming modifications, many tRNA modifying enzymes have been demonstrated or hypothesized to also play an important role in folding tRNA acting as tRNA chaperones. In this review, we summarize the known functions of tRNA modifying enzymes throughout the lifecycle of a tRNA molecule, from transcription to degradation. Thereby, we describe how tRNA modification and folding by tRNA modifying enzymes enhance tRNA maturation, tRNA aminoacylation, and tRNA function during protein synthesis, ultimately impacting cellular phenotypes and disease.

Novel method of synthesis of 5''-phosphate 2'-O-ribosyl-ribonucleosides and their 3'-phosphoramidites

Synthesis of 5''-phosphate 2'-O-ribosylribonucleosides [Nr(p)] of four common ribonucleosides, and 3'-phosphoramidites of 5''-phosphate 2'-O-ribosyladenosine and 2'-O-ribosylguanosine using the H-phosphonate chemistry is described. An additional ring protected by benzoyl groups was incorporated into the main ribosyl ring in the reaction with 1-O-acetyl-2,3,5-tri-O-benzoyl-β-D-ribofuranose in the presence of SnCl4. The obtained 2'-O-ribosylribonucleosides (Nr) were applied in the subsequent transformations with selective deprotection. Ethanolamine was applied as a very convenient reagent for selective removal of benzoyl groups. Additionally, the tetraisopropyldisiloxane-1,3-diyl (TIPDSi) group was found to be stable under these deprotection conditions. Thus, the selectively deprotected 5''-hydroxyl group of Nr was transformed into an H-phosphonate monoester which was found to be stable under the following conditions: the removal of the TIPDSi group with triethylammonium fluoride and the dimethoxytritylation of the 5''-hydroxyl function. The 5''-H-phosphonate of Nr precursors was easily transformed to the corresponding dicyanoethyl 5''-O-phosphotriesters before phosphitylation, which gave 3'-phosphoramidite units of Nr(p) in high yield. The derived phosphoramidite units were used in an automated oligonucleotide synthesizer to produce dimer Ar(p)T via the phosphoramidite approach. The obtained products were fully deprotected under standard deprotection conditions giving dimers with a 5''-phosphate monoester function. Application of an alkaline phosphatase to prove the presence of an additional phosphate group was described.

Structure and function of noncanonical nucleobases

DNA and RNA contain, next to the four canonical nucleobases, a number of modified nucleosides that extend their chemical information content. RNA is particularly rich in modifications, which is obviously an adaptation to their highly complex and variable functions. In fact, the modified nucleosides and their chemical structures establish a second layer of information which is of central importance to the function of the RNA molecules. Also the chemical diversity of DNA is greater than originally thought. Next to the four canonical bases, the DNA of higher organisms contains a total of four epigenetic bases: m(5) dC, hm(5) dC, f(5) dC und ca(5) dC. While all cells of an organism contain the same genetic material, their vastly different function and properties inside complex higher organisms require the controlled silencing and activation of cell-type specific genes. The regulation of the underlying silencing and activation process requires an additional layer of epigenetic information, which is clearly linked to increased chemical diversity. This diversity is provided by the modified non-canonical nucleosides in both DNA and RNA.

Iwr1 protein is important for preinitiation complex formation by all three nuclear RNA polymerases in Saccharomyces cerevisiae

BACKGROUND

Iwr1, a protein conserved throughout eukaryotes, was originally identified by its physical interaction with RNA polymerase (Pol) II.

PRINCIPAL FINDINGS

Here, we identify Iwr1 in a genetic screen designed to uncover proteins involved in Pol III transcription in S. cerevisiae. Iwr1 is important for Pol III transcription, because an iwr1 mutant strain shows reduced association of TBP and Pol III at Pol III promoters, a decreased rate of Pol III transcription, and lower steady-state levels of Pol III transcripts. Interestingly, an iwr1 mutant strain also displays reduced association of TBP to Pol I-transcribed genes and of both TBP and Pol II to Pol II-transcribed promoters. Despite this, rRNA and mRNA levels are virtually unaffected, suggesting a post-transcriptional mechanism compensating for the occupancy defect.

CONCLUSIONS

Thus, Iwr1 plays an important role in preinitiation complex formation by all three nuclear RNA polymerases.

LC-MS based quantification of 2'-ribosylated nucleosides Ar(p) and Gr(p) in tRNA

RNA nucleosides are often naturally modified into complex non-canonical structures with key biological functions. Here we report LC-MS quantification of the Ar(p) and Gr(p) 2'-ribosylated nucleosides in tRNA using deuterium labelled standards, and the first detection of Gr(p) in complex fungi.

Eukaryotic initiator tRNA: finely tuned and ready for action

The initiator tRNA must serve functions distinct from those of other tRNAs, evading binding to elongation factors and instead binding directly to the ribosomal P site with the aid of initiation factors. It plays a key role in decoding the start codon, setting the frame for translation of the mRNA. Sequence elements and modifications of the initiator tRNA distinguish it from the elongator methionyl tRNA and help it to perform its varied tasks. These identity elements appear to finely tune the structure of the initiator tRNA, and growing evidence suggests that the body of the tRNA is involved in transmitting the signal that the start codon has been found to the rest of the pre-initiation complex.

Queuosine modification of tRNA: its divergent role in cellular machinery

tRNAs possess a high content of modified nucleosides, which display an incredible structural variety. These modified nucleosides are conserved in their sequence and have important roles in tRNA functions. Most often, hypermodified nucleosides are found in the wobble position of tRNAs, which play a direct role in maintaining translational efficiency and fidelity, codon recognition, etc. One of such hypermodified base is queuine, which is a base analogue of guanine, found in the first anticodon position of specific tRNAs (tyrosine, histidine, aspartate and asparagine tRNAs). These tRNAs of the ‘Q-family’ originally contain guanine in the first position of anticodon, which is post-transcriptionally modified with queuine by an irreversible insertion during maturation. Queuine is ubiquitously present throughout the living system from prokaryotes to eukaryotes, including plants. Prokaryotes can synthesize queuine de novo by a complex biosynthetic pathway, whereas eukaryotes are unable to synthesize either the precursor or queuine. They utilize salvage system and acquire queuine as a nutrient factor from their diet or from intestinal microflora. The tRNAs of the Q-family are completely modified in terminally differentiated somatic cells. However, hypomodification of Q-tRNA (queuosine-modified tRNA) is closely associated with cell proliferation and malignancy. The precise mechanisms of queuine- and Q-tRNA-mediated action are still a mystery. Direct or indirect evidence suggests that queuine or Q-tRNA participates in many cellular functions, such as inhibition of cell proliferation, control of aerobic and anaerobic metabolism, bacterial virulence, etc. The role of Q-tRNA modification in cellular machinery and the signalling pathways involved therein is the focus of this review.

Unconventional decoding of the AUA codon as methionine by mitochondrial tRNAMet with the anticodon f5CAU as revealed with a mitochondrial in vitro translation system

Mitochondrial (mt) tRNA^Met has the unusual modified nucleotide 5-formylcytidine (f⁵C) in the first position of the anticodon. This tRNA must translate both AUG and AUA as methionine. By constructing an in vitro translation system from bovine liver mitochondria, we examined the decoding properties of the native mt tRNA^Met carrying f⁵C in the anticodon compared to a transcript that lacks the modification. The native mt Met-tRNA could recognize both AUA and AUG codons as Met, but the corresponding synthetic tRNA^Met lacking f⁵C (anticodon CAU), recognized only the AUG codon in both the codon-dependent ribosomal binding and in vitro translation assays. Furthermore, the Escherichia coli elongator tRNA^Met_m with the anticodon ac⁴CAU (ac⁴C = 4-acetylcytidine) and the bovine cytoplasmic initiator tRNA^Met (anticodon CAU) translated only the AUG codon for Met on mt ribosome. The codon recognition patterns of these tRNAs were the same on E. coli ribosomes. These results demonstrate that the f⁵C modification in mt tRNA^Met plays a crucial role in decoding the nonuniversal AUA codon as Met, and that the genetic code variation is compensated by a change in the tRNA anticodon, not by a change in the ribosome. Base pairing models of f⁵C-G and f⁵C-A based on the chemical properties of f⁵C are presented.

Incorporation of a S-glycosidic linkage into a glyconucleoside changes the conformational preference of both furanose sugars

A glyconucleoside containing a thioglycoside linkage, namely 1-(3-S-beta-D-ribofuranosyl-2,3-dideoxy-3-thio-beta-D-ribofuranosyl)-thymine, has been prepared through condensation of a suitably protected derivative of 3'-thiothymidine with an activated ribose sugar. NMR has been used to study the conformation of the S-disaccharide and the unmodified O-disaccharide. A full pseudorotational analysis showed that for the S-disaccharide, the ribose and deoxy ribose sugars have a preference for the south and north pucker, respectively; which is the reverse of what is seen for the O-disaccharide.

Yeast initiator tRNA identity elements cooperate to influence multiple steps of translation initiation

All three kingdoms of life employ two methionine tRNAs, one for translation initiation and the other for insertion of methionines at internal positions within growing polypeptide chains. We have used a reconstituted yeast translation initiation system to explore the interactions of the initiator tRNA with the translation initiation machinery. Our data indicate that in addition to its previously characterized role in binding of the initiator tRNA to eukaryotic initiation factor 2 (eIF2), the initiator-specific A1:U72 base pair at the top of the acceptor stem is important for the binding of the eIF2.GTP.Met-tRNA(i) ternary complex to the 40S ribosomal subunit. We have also shown that the initiator-specific G:C base pairs in the anticodon stem of the initiator tRNA are required for the strong thermodynamic coupling between binding of the ternary complex and mRNA to the ribosome. This coupling reflects interactions that occur within the complex upon recognition of the start codon, suggesting that these initiator-specific G:C pairs influence this step. The effect of these anticodon stem identity elements is influenced by bases in the T loop of the tRNA, suggesting that conformational coupling between the D-loop-T-loop substructure and the anticodon stem of the initiator tRNA may occur during AUG codon selection in the ribosomal P-site, similar to the conformational coupling that occurs in A-site tRNAs engaged in mRNA decoding during the elongation phase of protein synthesis.

The pathogenic A4269G mutation in human mitochondrial tRNA(Ile) alters the T-stem structure and decreases the binding affinity for elongation factor Tu

The A4269G mutation in the human mitochondrial (mt) tRNA(Ile) gene is associated with fatal cardiomyopathy. This mutation completely inhibits protein synthesis in mitochondria, thereby significantly reducing their respiratory activity. The steady-state amount of tRNA(Ile) in cells bearing the A4269G mutation is almost half that of control cells. We previously reported that this mutation causes tRNA(Ile) to be unstable both in vivo and in vitro. To investigate whether the instability of the mutant tRNA(Ile) is due to structural alterations, a nuclease-probing experiment was performed with a mitochondrial enzymatic extract, which showed that the A4269G mutation destabilizes the T-stem of the mutant tRNA(Ile). In addition, measurements of the binding affinity of the aminoacylated mutant tRNA(Ile) for mt elongation factor Tu (EF-Tu) showed that the mutant tRNA(Ile) binds mt EF-Tu less efficiently than the wild-type does. This observation provides insight into the molecular pathology associated with tRNA dysfunction caused by this pathogenic point mutation.

The Molecular Mechanics of Eukaryotic Translation

Great advances have been made in the past three decades in understanding the molecular mechanics underlying protein synthesis in bacteria, but our understanding of the corresponding events in eukaryotic organisms is only beginning to catch up. In this review we describe the current state of our knowledge and ignorance of the molecular mechanics underlying eukaryotic translation. We discuss the mechanisms conserved across the three kingdoms of life as well as the important divergences that have taken place in the pathway.

The T-stem determines the cytosolic or mitochondrial localization of trypanosomal tRNAsMet

The mitochondrion of Trypanosoma brucei lacks tRNA genes. Organellar translation therefore depends on import of cytosolic, nucleus-encoded tRNAs. Except for the cytosol-specific initiator tRNA(Met), all trypanosomal tRNAs function in both the cytosol and the mitochondrion. The initiator tRNA(Met) is closely related to the imported elongator tRNA(Met). Thus, the distinct localization of the two tRNAs(Met) must be specified by the 26 nucleotides, which differ between the two molecules. Using transgenic T. brucei cell lines and subsequent cell fractionation, we show that the T-stem is both required and sufficient to specify the localization of the tRNAs(Met). Furthermore, it was shown that the tRNA(Met) T-stem localization determinants are also functional in the context of two other tRNAs. In vivo analysis of the modified nucleotides found in the initiator tRNA(Met) indicates that the T-stem localization determinants do not require modified nucleotides. In contrast, import of native tRNAs(Met) into isolated mitochondria suggests that nucleotide modifications might be involved in regulating the extent of import of elongator tRNA(Met).

Common location of determinants in initiator transfer RNAs for initiator-elongator discrimination in bacteria and in eukaryotes

Initiator tRNAs are used exclusively for initiation of protein synthesis and not for elongation. We show that both Escherichia coli and eukaryotic initiator tRNAs have negative determinants, at the same positions, that block their activity in elongation. The primary negative determinant in E. coli initiator tRNA is the C1xA72 mismatch at the end of the acceptor stem. The primary negative determinant in eukaryotic initiator tRNAs is located in the TPsiC stem, whereas a secondary negative determinant is the A1:U72 base pair at the end of the acceptor stem. Here we show that E. coli initiator tRNA also has a secondary negative determinant for elongation and that it is the U50.G64 wobble base pair, located at the same position in the TPsiC stem as the primary negative determinant in eukaryotic initiator tRNAs. Mutation of the U50.G64 wobble base pair to C50:G64 or U50:A64 base pairs increases the in vivo amber suppressor activity of initiator tRNA mutants that have changes in the acceptor stem and in the anticodon sequence necessary for amber suppressor activity. Binding assays of the mutant aminoacyl-tRNAs carrying the C50 and A64 changes to the elongation factor EF-Tu.GTP show marginally higher affinity of the C50 and A64 mutant tRNAs and increased stability of the EF-Tu.GTP. aminoacyl-tRNA ternary complexes. Other results show a large effect of the amino acid attached to a tRNA, glutamine versus methionine, on the binding affinity toward EF-Tu.GTP and on the stability of the EF-Tu.GTP.aminoacyl-tRNA ternary complex.

A critical role of water in the specific cleavage of the anticodon loop of some eukaryotic methionine initiator tRNAs

We have noticed that during a long storage and handling, the plant methionine initiator tRNA is spontaneously hydrolyzed within the anticodon loop at the C34-A35 phosphodiester bond. A literature search indicated that there is also the case for human initiator tRNA(Met) but not for yeast tRNA(i)Met or E. coli tRNA(f)Met. All these tRNAs have an identical nucleotide sequence of the anticodon stems and loops with only one difference at position 33 within the loop. It means that cytosine 33 (C33) makes the anticodon loop of plant and human tRNA(i)Met susceptible to the specific cleavage reaction. Using crystallographic data of tRNA(f)Met of E. coli with U33, we modeled the anticodon loop of this tRNA with C33. We found that C33 within the anticodon loop creates a pocket that can accomodate a hydrogen bonded water molecule that acts as a general base and catalyzes a hydrolysis of C-A bond. We conclude that a single nucleotide change in the primary structure of tRNA(i)Met made changes in hydration pattern and readjustment in hydrogen bonding which lead to a cleavage of the phosphodiester bond.

Preparation and activity of synthetic unmodified mammalian tRNAi(Met) in initiation of translation in vitro

Translation of eukaryotic mRNA is initiated by a unique amino-acyl tRNA, Met-tRNAi(Met), which passes through a complex series of highly specific interactions with components of the translation apparatus during the initiation process. To facilitate in vitro biochemical and molecular biological analysis of these interactions in fully reconstituted translation initiation reactions, we generated mammalian tRNAi(Met) by in vitro transcription that lacked all eight base modifications present in native tRNAi(Met). Here we report a method for in vitro transcription and aminoacylation of synthetic unmodified initiator tRNAi(Met) that is active in every stage of the initiation process, including aminoacylation by methionyl-tRNA synthetase, binding of Met-tRNAi(Met) to eIF2-GTP to form a ternary complex, binding of the ternary complexes to 40S ribosomal subunits to form 43S complexes, binding of the 43S complex to a native capped eukaryotic mRNA, and scanning on its 5' untranslated region to the correct initiation codon to form a 48S complex, and finally joining with a 60S subunit to assemble an 80S ribosome that is competent to catalyze formation of the first peptide bond using the [35S]methionine residue attached to the acceptor terminus of the tRNAi(Met) transcript.

An "elongated" translation elongation factor Tu for truncated tRNAs in nematode mitochondria

We have found the gene for a translation elongation factor Tu (EF-Tu) homologue in the genome of the nematode Caenorhabditis elegans. Because the corresponding protein was detected immunologically in a nematode mitochondrial (mt) extract, it could be regarded as a nematode mt EF-Tu. The protein possesses an extension of about 57 amino acids (we call this domain 3') at the C terminus, which is not found in any other known EF-Tu. Because most nematode mt tRNAs lack a T stem, domain 3' may be related to this feature. The nematode EF-Tu bound to nematode T stem-lacking tRNA, but bacterial EF-Tu was unable to do so. A series of domain exchange experiments strongly suggested that domains 3 and 3' are essential for binding to T stem-lacking tRNAs. This finding may constitute a novel example of the co-evolution of a structurally simplified RNA and the cognate RNA-binding protein, the latter having apparently acquired an additional domain to compensate for the lack of a binding site(s) on the RNA.

Quantitative assessment of EF-1alpha.GTP binding to aminoacyl-tRNAs, aminoacyl-viral RNA, and tRNA shows close correspondence to the RNA binding properties of EF-Tu

A ribonuclease protection assay was used to determine the equilibrium dissociation constants (Kd) for the binding of various RNAs by wheat germ EF-1alpha.GTP. Aminoacylated fully modified tRNAs and unmodified tRNA transcripts of four specificities (valyl, methionyl, alanyl, and phenylalanyl) from higher plants or Escherichia coli were bound with Kd values between 0.8 and 10 nM. A valylated 3'-fragment of turnip yellow mosaic virus RNA, which has a pseudoknotted amino acid acceptor stem, was bound with affinity similar to that of Val-tRNAVal. Uncharged tRNA and initiator Met-tRNAMet from wheat germ, RNAs that are normally excluded from the ribosomal A site in vivo, bound weakly. The discrimination against wheat germ initiator Met-tRNAMet was almost entirely due to the 2'-phosphoribosyl modification at nucleotide G64, since removal resulted in tight binding by EF-1alpha.GTP. A 44-nucleotide RNA representing a kinked acceptor/T arm obtained by in vitro selection to bacterial EF-Tu formed an Ala-RNA.EF-1alpha.GTP complex with a Kd of 29 nM, indicating that much of the binding affinity for aminoacylated tRNA is derived from interaction with the acceptor/T half of the molecule. The pattern of tRNA interaction observed for EF-1alpha (eEF1A) therefore closely resembles that of bacterial EF-Tu (EF1A).

Initiator-elongator discrimination in vertebrate tRNAs for protein synthesis

Initiator tRNAs are used exclusively for initiation of protein synthesis and not for the elongation step. We show, in vivo and in vitro, that the primary sequence feature that prevents the human initiator tRNA from acting in the elongation step is the nature of base pairs 50:64 and 51:63 in the TpsiC stem of the initiator tRNA. Various considerations suggest that this is due to sequence-dependent perturbation of the sugar phosphate backbone in the TpsiC stem of initiator tRNA, which most likely blocks binding of the elongation factor to the tRNA. Because the sequences of all vertebrate initiator tRNAs are identical, our findings with the human initiator tRNA are likely to be valid for all vertebrate systems. We have developed reporter systems that can be used to monitor, in mammalian cells, the activity in elongation of mutant human initiator tRNAs carrying anticodon sequence mutations from CAU to CCU (the C35 mutant) or to CUA (the U35A36 mutant). Combination of the anticodon sequence mutation with mutations in base pairs 50:64 and 51:63 yielded tRNAs that act as elongators in mammalian cells. Further mutation of the A1:U72 base pair, which is conserved in virtually all eukaryotic initiator tRNAs, to G1:C72 in the C35 mutant background yielded tRNAs that were even more active in elongation. In addition, in a rabbit reticulocyte in vitro protein-synthesizing system, a tRNA carrying the TpsiC stem and the A1:U72-to-G1:C72 mutations was almost as active in elongation as the elongator methionine tRNA. The combination of mutant initiator tRNA with the CCU anticodon and the reporter system developed here provides the first example of missense suppression in mammalian cells.

Antideterminants present in minihelix(Sec) hinder its recognition by prokaryotic elongation factor Tu

During protein biosynthesis, all aminoacylated elongator tRNAs except selenocysteine-inserting tRNA Sec form ternary complexes with activated elongation factor. tRNA Sec is bound by its own translation factor, an elongation factor analogue, e.g. the SELB factor in prokaryotes. An apparent reason for this discrimination could be related to the unusual length of tRNA Sec amino acid-acceptor branch formed by 13 bp. However, it has been recently shown that an aspartylated minihelix of 13 bp derived from yeast tRNA Asp is an efficient substrate for Thermus thermophilus EF-Tu-GTP, suggesting that features other than the length of tRNA Sec prevent its recognition by EF-Tu-GTP. A stepwise mutational analysis of a minihelix derived from tRNA Sec in which sequence elements of tRNA Asp were introduced showed that the sequence of the amino acid- acceptor branch of Escherichia coli tRNA Sec contains a specific structural element that hinders its binding to T.thermophilus EF-Tu-GTP. This antideterminant is located in the 8th, 9th and 10th bp in the acceptor branch of tRNA Sec, corresponding to the last base pair in the amino acid acceptor stem and the two first pairs in the T-stem. The function of this C7.G66/G49.U65/C50.G64 box was tested by its transplantation into a minihelix derived from tRNA Asp, abolishing its recognition by EF-Tu-GTP. The specific role of this nucleotide combination is further supported by its absence in all known prokaryotic elongator tRNAs.

Effect of modified nucleotides on structure of yeast tRNA(Phe). Comparative studies by metal ion-induced hydrolysis and nuclease mapping

Structural differences between native yeast tRNA(Phe), its in vitro transcript and the U8G mutant have been investigated using metal ion-induced hydrolysis and nuclease digestion. Differences in the solution structure of the molecules involve four regions: the D- and T-loops, the variable region and the anticodon loop. Efficiency of the Pb(II); Eu(II)-, Mn(II)- and Mg(II)-induced hydrolysis at the main cleavage sites in the D-loop is significantly reduced for unmodified tRNAs. Moreover, only the in vitro transcripts are susceptible for cleavage in the T-loop and entire anticodon loop. Other changes in the transcript molecule involve 50-fold enhancement of S1 nuclease digestion at p36, weak cleavages in the D-loop and lack of some digestion sites in the T-loop. The nuclease V1 digestion patterns are very similar for studied molecules. Changes in the pattern of hydrolysis of the D-loop caused by mutation of the conservative base U8 to G are detected by metal-induced hydrolysis only. Our results indicate clearly that metal ions and enzymatic probes monitor different features of RNA structure and their combined use is highly advantageous in studying subtle structural changes in tRNA.

The ternary complex of aminoacylated tRNA and EF-Tu-GTP. Recognition of a bond and a fold

The refined crystal structure of the ternary complex of yeast Phe-tRNAPhe, Thermus aquaticus elongation factor EF-Tu and the non-hydrolyzable GTP analog, GDPNP, reveals many details of the EF-Tu recognition of aminoacylated tRNA (aa-tRNA). EF-Tu-GTP recognizes the aminoacyl bond and one side of the backbone fold of the acceptor helix and has a high affinity for all ordinary elongator aa-tRNAs by binding to this aa-tRNA motif. Yet, the binding of deacylated tRNA, initiator tRNA, and selenocysteine-specific tRNA (tRNASec) is effectively discriminated against. Subtle rearrangements of the binding pocket may occur to optimize the fit to any side chain of the aminoacyl group and interactions with EF-Tu stabilize the 3'-aminoacyl isomer of aa-tRNA. A general complementarity is observed in the location of the binding sites in tRNA for synthetases and for EF-Tu. The complex formation is highly specific for the GTP-bound conformation of EF-Tu, which can explain the effects of various mutants.

Molecular recognition governing the initiation of translation in Escherichia coli. A review

Selection of the proper start codon for the synthesis of a polypeptide by the Escherichia coli translation initiation apparatus involves several macromolecular components. These macromolecules interact in a specific and concerted manner to yield the translation initiation complex. This review focuses on recent data concerning the properties of the initiator tRNA and of enzymes and factors involved in the translation initiation process. The three initiation factors, as well as methionyl-tRNA synthetase and methionyl-tRNA(f)Met formyltransferase are described. In addition, the tRNA recognition properties of EF-Tu and peptidyl-tRNA hydrolase are considered. Finally, peptide deformylase and methionine aminopeptidase, which catalyze the amino terminal maturation of nascent polypeptides, can also be associated to the translation initiation process.

Rit1, a tRNA backbone-modifying enzyme that mediates initiator and elongator tRNA discrimination

Using a genetic screen in yeast aimed at identifying cellular factors involved in initiator and elongator methionine tRNA discrimination in the translational process, we have identified a mutation that abolish the requirement for elongator methionine tRNA. The gene affected, which we call the ribosylation of the initiator tRNA gene or RIT1, encodes a 2'-O-ribosyl phosphate transferase. This enzyme modifies exclusively the initiator tRNA in position 64 using 5'-phosphoribosyl-1'-pyrophosphate as the modification donor. As the initiator tRNA participates both in the initiation and elongation of translation in a rit1 strain, we conclude that the 2'-O-ribosyl phosphate modification discriminates the initiator tRNAs from the elongator tRNAs during protein synthesis. The modification enzyme was shown to recognize the stem-loop IV region that is unique in eukaryotic cytoplasmic initiator tRNAs.