tRNA nucleotide 47: an evolutionary enigma.

A previous analysis of tRNA sequences suggested a correlation between the absence of a nucleotide at position 47 (nt 47) in the extra loop and the presence of a U13:G22 base pair in the D-stem. We have evaluated the significance of this correlation by determining the in vivo activity of tRNAs containing either a C13:G22 or a U13:G22 pair in tRNA molecules with or without nt 47. Although this correlation might reflect some malfunction of tRNAs lacking nt 47, but containing the C13:G22, assays of the in vivo suppressor activity showed that this tRNA is actually more active than the tRNA with the features found in the database, i.e., a U13:G22 base pair and no nt 47. Moreover, analogous constructs with a GGC anticodon permitted the growth of an Escherichia coli strain deleted for tRNA(Ala)GGC genes equally well. On the other hand, long-term growth experiments with competing E. coli strains harboring the tRNA lacking nt 47, either with the C13:G22 or the U13:G22 base pair demonstrated that the U13:G22 tRNA overtook the C13:G22 strain even when the starting proportion of strains favored the C13:G22 strain. Thus, the preference for the U13:G22 tRNA lacking nt 47 in the sequence database is most likely due to factors that come into play during extended growth or latency rather than to the ability of the tRNA to engage in protein synthesis.     

tRNA discrimination by T. thermophilus phenylalanyl-tRNA synthetase at the binding step

The extent of tRNA recognition at the level of binding by Thermus thermophilus phenylalanyl-tRNA synthetase (PheRS), one of the most complex class II synthetases, has been studied by independent measurements of the enzyme association with wild-type and mutant tRNA(Phe)s as well as with non-cognate tRNAs. The data obtained, combined with kinetic data on aminoacylation, clearly show that PheRS exhibits more tRNA selectivity at the level of binding than at the level of catalysis. The anticodon nucleotides involved in base-specific interactions with the enzyme prevail both in the initial binding recognition and in favouring aminoacylation catalysis. Tertiary nucleotides of base pair G19-C56 and base triple U45-G10-C25 contribute primarily to stabilization of the correctly folded tRNA(Phe) structure, which is important for binding. Other nucleotides of the central core (U20, U16 and of the A26-G44 tertiary base pair) are involved in conformational adjustment of the tRNA upon its interaction with the enzyme. The specificity of nucleotide A73, mutation of which slightly reduces the catalytic rate of aminoacylation, is not displayed at the binding step. A few backbone-mediated contacts of PheRS with the acceptor and anticodon stems revealed in the crystal structure do not contribute to tRNA(Phe) discrimination, their role being limited to stabilization of the complex. The highest affinity of T. thermophilus PheRS for cognate tRNA, observed for synthetase-tRNA complexes, results in 100-3000-fold binding discrimination against non-cognate tRNAs.     

Key elements in maintenance of the tRNA L-shape

Based on in vivo selection of effective suppressor tRNAs from two different combinatorial gene libraries in which several nucleotides in the D and T-loops were randomized, we show that the position of the reverse-Hoogsteen base-pair in the T-loop, normally formed between nucleotides 54-58, co-varies with the length of the D-domain. When the D-domain has the normal length, the position of the reverse-Hoogsteen base-pair in the T-loop is always such that it allocates two unpaired nucleotides 59-60 for the bulge that fills the space between the D and T-domains. However, when the D-domain becomes shorter, the position of the reverse-Hoogsteen base-pair changes in the way that more nucleotides are now allocated to the T-loop bulge, so that the total length of the D-domain and of the bulge remains the same. Such compensation guarantees that in all tRNAs, the D and T-domains are always juxtaposed in the standard way. It also demonstrates the major role of the two T-loop elements, the bulge and the reverse-Hoogsteen base-pair, in the formation of the canonical tRNA L-shape.     

Wobble modification differences and subcellular localization of tRNAs in Leishmania tarentolae: implication for tRNA sorting mechanism

In Leishmania tarentolae, all mitochondrial tRNAs are encoded in the nuclear genome and imported from the cytosol. It is known that tRNA(Glu)(UUC) and tRNA(Gln)(UUG) are localized in both cytosol and mitochondria. We investigated structural differences between affinity-isolated cytosolic (cy) and mitochondrial (mt) tRNAs for glutamate and glutamine by mass spectrometry. A unique modification difference in both tRNAs was identified at the anticodon wobble position: cy tRNAs have 5-methoxycarbonylmethyl-2- thiouridine (mcm(5)s(2)U), whereas mt tRNAs have 5- methoxycarbonylmethyl-2'-O-methyluridine (mcm(5)Um). In addition, a trace portion (4%) of cy tRNAs was found to have 5-methoxycarbonylmethyluridine (mcm(5)U) at its wobble position, which could represent a common modification intermediate for both modified uridines in cy and mt tRNAs. We also isolated a trace amount of mitochondria-specific tRNA(Lys)(UUU) from the cytosol and found mcm(5)U at its wobble position, while its mitochondrial counterpart has mcm(5)Um. Mt tRNA(Lys) and in vitro transcribed tRNA(Glu) were imported much more efficiently into isolated mitochondria than the native cy tRNA(Glu) in an in vitro importation experiment, indicating that cytosol-specific 2-thiolation could play an inhibitory role in tRNA import into mitochondria.     

Influence of transfer RNA tertiary structure on aminoacylation efficiency by glutaminyl and cysteinyl-tRNA synthetases

The position of the tertiary Levitt pair between nucleotides 15 and 48 in the transfer RNA core region suggests a key role in stabilizing the joining of the two helical domains, and in maintaining the relative orientations of the D and variable loops. E. coli tRNA(Gln) possesses the canonical Pu15-Py48 trans pairing at this position (G15-C48), while the tRNA(Cys) species from this organism instead features an unusual G15-G48 pair. To explore the structural context dependence of a G15-G48 Levitt pair, a number of tRNA(Gln) species containing G15-G48 were constructed and evaluated as substrates for glutaminyl and cysteinyl-tRNA synthetases. The glutaminylation efficiencies of these mutant tRNAs are reduced by two to tenfold compared with native tRNA(Gln), consistent with previous findings that the tertiary core of this tRNA plays a role in GlnRS recognition. Introduction of tRNA(Cys) identity nucleotides at the acceptor and anticodon ends of tRNA(Gln) produced a tRNA substrate which was efficiently aminoacylated by CysRS, even though the tertiary core region of this species contains the tRNA(Gln) G15-C48 pair. Surprisingly, introduction of G15-G48 into the non-cognate tRNA(Gln) tertiary core then significantly impairs CysRS recognition. By contrast, previous work has shown that CysRS aminoacylates tRNA(Cys) core regions containing G15-G48 with much better efficiency than those with G15-C48. Therefore, tertiary nucleotides surrounding the Levitt pair must significantly modulate the efficiency of aminoacylation by CysRS. To explore the detailed nature of the structural interdependence, crystal structures of two tRNA(Gln) mutants containing G15-G48 were determined bound to GlnRS. These structures show that the larger purine ring of G48 is accommodated by rotation into the syn position, with the N7 nitrogen serving as hydrogen bond acceptor from several groups of G15. The G15-G48 conformations differ significantly compared to that observed in the native tRNA(Cys) structure bound to EF-Tu, further implicating an important role for surrounding nucleotides in maintaining the integrity of the tertiary core and its consequent ability to present crucial recognition determinants to aminoacyl-tRNA synthetases.     

Identification and codon reading properties of 5-cyanomethyl uridine,a new modified nucleoside found in the anticodon wobble position of mutant haloarchaeal isoleucine tRNAs

Most archaea and bacteria use a modified C in the anticodon wobble position of isoleucine tRNA to base pair with A but not with G of the mRNA. This allows the tRNA to read the isoleucine codon AUA without also reading the methionine codon AUG. To understand why a modified C, and not U or modified U, is used to base pair with A, we mutated the C34 in the anticodon of Haloarcula marismortui isoleucine tRNA (tRNA₂^Ile) to U, expressed the mutant tRNA in Haloferax volcanii, and purified and analyzed the tRNA. Ribosome binding experiments show that although the wild-type tRNA₂^Ile binds exclusively to the isoleucine codon AUA, the mutant tRNA binds not only to AUA but also to AUU, another isoleucine codon, and to AUG, a methionine codon. The G34 to U mutant in the anticodon of another H. marismortui isoleucine tRNA species showed similar codon binding properties. Binding of the mutant tRNA to AUG could lead to misreading of the AUG codon and insertion of isoleucine in place of methionine. This result would explain why most archaea and bacteria do not normally use U or a modified U in the anticodon wobble position of isoleucine tRNA for reading the codon AUA. Biochemical and mass spectrometric analyses of the mutant tRNAs have led to the discovery of a new modified nucleoside, 5-cyanomethyl U in the anticodon wobble position of the mutant tRNAs. 5-Cyanomethyl U is present in total tRNAs from euryarchaea but not in crenarchaea, eubacteria, or eukaryotes.     

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.     

Importance of the reverse Hoogsteen base pair 54-58 for tRNA function

To elucidate the general constraints imposed on the structure of the D- and T-loops in functional tRNAs, active suppressor tRNAs were selected in vivo from a combinatorial tRNA gene library in which several nucleotide positions of these loops were randomized. Analysis of the nucleotide sequences of the selected clones demonstrates that among the randomized nucleotides, the most conservative are nucleotides 54 and 58 in the T-loop. In most cases, they make the combination U54-A58, which allows the formation of the normal reverse Hoogsteen base pair. Surprisingly, other clones have either the combination G54-A58 or G54-G58. However, molecular modeling shows that these purine–purine base pairs can very closely mimic the reverse Hoogsteen base pair U-A and thus can replace it in the T-loop of a functional tRNA. This places the reverse Hoogsteen base pair 54-58 as one of the most important structural aspects of tRNA functionality. We suggest that the major role of this base pair is to preserve the conformation of dinucleotide 59–60 and, through this, to maintain the general architecture of the tRNA L-form.     

Conformational energy and structure in canonical and noncanonical forms of tRNA determined by temperature analysis of the rate of s(4)U8-C13 photocrosslinking

Bacterial tRNAs frequently have 4-thiouridine (s(4)U) modification at position 8, which is adjacent to the C13-G22-m(7)G46 base triple in the elbow region of the tRNA tertiary structure. Irradiation with light in the UVA range induces an efficient photocrosslink between s(4)U8 and C13. The temperature dependence of the rate constants for photocrosslinking between the s(4)U8 and C13 has been used to investigate the tRNA conformational energy and structure in Escherichia coli tRNA(Val), tRNA(Phe), and tRNA(fMet) under different conditions. Corrections have been made in the measured rate constants to compensate for differences in the excited state lifetimes due to tRNA identity, buffer conditions, and temperature. The resulting rate constants are related to the rate at which the s(4)U8 and C13 come into the alignment needed for photoreaction; this depends on an activation energy, attributable to the conformational potential energy that occurs during the photoreaction, and on the extent of the structural change. Different photocrosslinking rate constants and temperature dependencies occur in the three tRNAs, and these differences are due both to modest differences in the activation energies and in the apparent s(4)U8-C13 geometries. Analysis of tRNA(Val) in buffers without Mg(2+) indicate a smaller activation energy (~13 kJ mol(-1)) and a larger apparent s(4)U8-C13 distance (~12 A) compared to values for the same parameters in buffers with Mg(2+) (~26 kJ mol(-1) and 0.36 A, respectively). These measurements are a quantitative indication of the strong constraint that Mg(2+) imposes on the tRNA flexibility and structure.     

Three Tetrahymena tRNA(Gln) isoacceptors as tools for studying unorthodox codon recognition and codon context effects during protein synthesis in vitro.

Three glutamine tRNA isoacceptors are known in Tetrahymena thermophila. One of these has the anticodon UmUG which reads the two normal glutamine codons CAA and CAG, whereas the two others with CUA and UmUA anticodons recognize UAG and UAA, respectively, which serve as termination codons in other organisms. We have employed these tRNA(Gln)-isoacceptors as tools for studying unconventional base interactions in a mRNA- and tRNA-dependent wheat germ extract. We demonstrate here (i) that tRNA(Gln)UmUG suppresses the UAA as well as the UAG stop codon, involving a single G:U wobble pair at the third anticodon position and two simultaneous wobble base pairings at the first and third position, respectively, and (ii) that tRNA(Gln)CUA, in addition to its cognate codon UAG, reads the UAA stop codon which necessitates a C:A mispairing in the first anticodon position. These unorthodox base interactions take place in a codon context which favours readthrough in tobacco mosaic virus (TMV) or tobacco rattle virus (TRV) RNA, but are not observed in a context that terminates zein and globin protein synthesis. Furthermore, our data reveal that wobble or mispairing in the middle position of anticodon-codon interactions is precluded in either context. The suppressor activities of tRNAs(Gln) are compared with those of other known naturally occurring suppressor tRNAs, i.e., tRNA(Tyr)G psi A and tRNA(Trp)CmCA. Our results indicate that a 'leaky' context is neither restricted to a single stop codon nor to a distinct tRNA species.     

The nucleotide sequence and characterization of four chloroplast tRNAs from the alga codium fragile

The nucleotide sequences of four chloroplast tRNAs (methionine elongator, lysine, glycine, and arginine) from the siphonaceous green alga Codium fragile have been determined. These tRNAs have an unusually high A-U content compared to other chloroplast tRNAs and show varied, but in general only limited, sequence homology to the corresponding tRNAs of other chloroplasts. The locations of the genes for these four tRNAs have been determined and they show no similarity to the location of the corresponding tRNA genes in other chloroplasts. The Codium chloroplast glycine tRNA has an unmodified uridine in the wobble position of the anticodon, a characteristic rarely found in tRNA but present in mitochondrial tRNAs which read the genetic code by extended wobble.     

Codon reading by tRNAAla with modified uridine in the wobble position

tRNAs reading four-codon families often have a modified uridine, cmo(5)U(34), at the wobble position of the anticodon. Here, we examine the effects on the decoding mechanism of a cmo(5)U modification in tRNA(1B)(Ala), anticodon C(36)G(35)cmo(5)U(34). tRNA(1B)(Ala) reads its cognate codons in a manner that is very similar to that of tRNA(Phe). As Ala codons are GC rich and Phe codons AU rich, this similarity suggests a uniform decoding mechanism that is independent of the GC content of the codon-anticodon duplex or the identity of the tRNA. The presence of cmo(5)U at the wobble position of tRNA(1B)(Ala) permits fairly efficient reading of non-Watson-Crick and nonwobble bases in the third codon position, e.g., the GCC codon. The ribosome accepts the C-cmo(5)U pair as an almost-correct base pair, unlike third-position mismatches, which lead to the incorporation of incorrect amino acids and are efficiently rejected.     

The anticodon and the D-domain sequences are essential determinants for plant cytosolic tRNA(Val) import into mitochondria

In higher plants, one-third to one-half of the mitochondrial tRNAs are encoded in the nucleus and are imported into mitochondria. This process appears to be highly specific for some tRNAs, but the factors that interact with tRNAs before and/or during import, as well as the signals present on the tRNAs, still need to be identified. The rare experiments performed so far suggest that, besides the probable implication of aminoacyl-tRNA synthetases, at least one additional import factor and/or structural features shared by imported tRNAs must be involved in plant mitochondrial tRNA import. To look for determinants that direct tRNA import into higher plant mitochondria, we have transformed BY2 tobacco cells with Arabidopsis thaliana cytosolic tRNA(Val)(AAC) carrying various mutations. The nucleotide replacements introduced in this naturally imported tRNA correspond to the anticodon and/or D-domain of the non-imported cytosolic tRNA(Met-e). Unlike the wild-type tRNA(Val)(AAC), a mutant tRNA(Val) carrying a methionine CAU anticodon that switches the aminoacylation of this tRNA from valine to methionine is not present in the mitochondrial fraction. Furthermore, mutant tRNAs(Val) carrying the D-domain of the tRNA(Met-e), although still efficiently recognized by the valyl-tRNA synthetase, are not imported any more into mitochondria. These data demonstrate that in plants, besides identity elements required for the recognition by the cognate aminoacyl-tRNA synthetase, tRNA molecules contain other determinants that are essential for mitochondrial import selectivity. Indeed, this suggests that the tRNA import mechanism occurring in plant mitochondria may be different from what has been described so far in yeast or in protozoa.     

The difference in the type of codon-anticodon base pairing at the ribosomal P-site is one of the determinants of the translational rate

By utilizing an enzymatically reconstructed tRNA variant containing an altered anticodon sequence, we have examined the different biochemical behavior of translation between the Watson-Crick type and the wobble type base pair interactions at the first anticodon position. We have found that the Watson-Crick type base pair has an advantage in translation in contrast to the wobble type base pair by comparing the efficiency of transpeptidation of native tRNA(Phe) (anticodon; GmAA) with its variant tRNA (anticodon; AAA) in the poly(U)-programmed ribosome system. Thomas et al. [Proc. Natl. Acad. Sci. U.S. (1988) 85, 4242-4246] showed that the wobble codon at the ribosomal A-site accepted its cognate tRNA less efficiently than the Watson-Crick base pairing codon. We report here that the wobble interaction at the ribosomal P-site also affected the rate of translation. This variable translational rate may be a mechanism of gene regulation through preferential codon usage.     

Unique secondary and tertiary structural features of the eucaryotic selenocysteine tRNA(Sec).

Cotranslational insertion of selenocysteine into selenoenzymes is mediated by a specialized transfer RNA, the tRNA(Sec). We have carried out the determination of the solution structure of the eucaryotic tRNA(Sec). Based on the enzymatic and chemical probing approach, we show that the secondary structure bears a few unprecedented features like a 9 bp aminoacid-, a 4 bp thymine- and a 6 bp dihydrouridine-stems. Surprisingly, the eighth nucleotide, although being a uridine, is base-paired and cannot therefore correspond to the single-stranded invariant U8 found in all tRNAs. Rather, experimental evidence led us to propose that the role of the invariant U8 is actually played by the tenth nucleotide which is an A, numbered A8 to indicate this fact. The experimental data therefore demonstrate that the cloverleaf structure we derived experimentally resembles the hand-folded model proposed by Böck et al (ref. 3). Using the solution data and computer modelling, we derived a three-dimensional structure model which shows some unique aspects. Basically, A8, A14, U21 form a novel type of tertiary interaction in which A8 interacts with the Hoogsteen sites of A14 which itself forms a Watson-Crick pair with U21. No coherent model containing the canonical 15-48 interaction could be derived. Thus, the number of tertiary interactions appear to be limited, leading to an uncoupling of the variable stem from the rest of the molecule.     

The wobble hypothesis revisited: uridine-5-oxyacetic acid is critical for reading of G-ending codons

According to Crick's wobble hypothesis, tRNAs with uridine at the wobble position (position 34) recognize A- and G-, but not U- or C-ending codons. However, U in the wobble position is almost always modified, and Salmonella enterica tRNAs containing the modified nucleoside uridine-5-oxyacetic acid (cmo⁵U34) at this position are predicted to recognize U- (but not C-) ending codons, in addition to A- and G-ending codons. We have constructed a set of S. enterica mutants with only the cmo⁵U-containing tRNA left to read all four codons in the proline, alanine, valine, and threonine family codon boxes. From the phenotypes of these mutants, we deduce that the proline, alanine, and valine tRNAs containing cmo⁵U read all four codons including the C-ending codons, while the corresponding threonine tRNA does not. A cmoB mutation, leading to cmo⁵U deficiency in tRNA, was introduced. Monitoring A-site selection rates in vivo revealed that the presence of cmo⁵U34 stimulated the reading of CCU and CCC (Pro), GCU (Ala), and GUC (Val) codons. Unexpectedly, cmo⁵U is critical for efficient decoding of G-ending Pro, Ala, and Val codons. Apparently, whereas G34 pairs with U in mRNA, the reverse pairing (U34-G) requires a modification of U34.     

Site-directed in vitro replacement of nucleosides in the anticodon loop of tRNA: application to the study of structural requirements for queuine insertase activity.

We have investigated the specificity of the enzymes Q-insertase and mannosyl-Q transferase that replace the guanosine at position 34 (wobble base) in the anticodon of several tRNAs by Q or mannosyl-Q derivatives. We have restructured in vitro the normal anticodon of yeast tRNA-Asp-GUC, yeast tRNAArgICG and yeast tRNALeuUAG. With yeast tRNA-Asp-GUC, we have replaced one or several nucleotides in the vicinity of G34 by one of the four canonical nucleotides or by pseudouridylic acid; we have also constructed a tRNAAsp with eight bases instead of seven in the anticodon loop. With yeast tRNAArgICG and yeast tRNALeuUAG, we have replaced their anticodon by the trinucleotide GUC, coding for aspartic acid. The chimerical tRNAs were microinjected into the cytoplasm of Xenopus laevis oocytes and after 72 h the amount of Q34 and mannosyl-Q34 incorporated was measured. Our results show that the U33G34U35 sequence, within an anticodon loop of seven bases in chimerical yeast tRNA-Asp-GUC, tRNAArgGUC or tRNALeuGUC, is the main determinant for Q-insertase activity at position 34; the rest of the tRNA sequence has only a slight influence. For mannosyl-Q transferase, however, a much broader structural feature of the tRNA than just the U33G34U35 sequence is important for the efficiency of Q34 transformation into mannosyl-Q34.