T-armless tRNAs and elongated elongation factor Tu

Most tRNAs share a common secondary structure containing a T arm, a D arm, an anticodon arm and an acceptor stem. However, there are some exceptions. Most nematode mitochondrial tRNAs and some animal mitochondrial tRNAs lack the T arm, which is necessary for binding to canonical elongation factor Tu (EF-Tu). The mitochondria of the nematode Caenorhabditis elegans have a unique EF-Tu, named EF-Tu1, whose structure has supplied clues as to how truncated tRNAs can work in translation. EF-Tu1 has a C-terminal extension of about 60 aa that is absent in canonical EF-Tu. Recent data from our laboratory strongly suggests that EF-Tu1 recognizes the D-arm instead of the T arm by a mechanism involving this C-terminal region. Further biochemical analysis of mitochondrial tRNAs and EF-Tu from the distantly related nematode Trichinella spp. and sequence information on nuclear and mitochondrial DNA in arthropods suggest that T-armless tRNAs may have arisen as a result of duplication of the EF-Tu gene. These studies provide valuable insights into the co-evolution of RNA and RNA-binding proteins.     

A unique serine-specific elongation factor Tu found in nematode mitochondria

The translation elongation factor Tu (EF-Tu) delivers aminoacyl-tRNAs to ribosomes by recognizing the tRNA acceptor and T stems. However, the unusual truncation observed in some animal mitochondrial tRNAs seems to prevent recognition by a canonical EF-Tu. For instance, nematode mitochondria contain tRNAs lacking a T or D arm. We recently found an atypical EF-Tu (EF-Tu1) specific for nematode mitochondrial tRNAs that lack the T arm. We have now discovered a second factor, EF-Tu2, which binds only to tRNAs that lack a D arm. EF-Tu2 seems unique in its amino acid specificity because it recognizes the aminoacyl moiety of seryl-tRNAs and the tRNA structure itself. Such EF-Tu evolution might explain tRNA structural divergence in animal mitochondria.     

A unique tRNA recognition mechanism of Caenorhabditis elegans mitochondrial EF-Tu2

Nematode mitochondria expresses two types of extremely truncated tRNAs that are specifically recognized by two distinct elongation factor Tu (EF-Tu) species named EF-Tu1 and EF-Tu2. This is unlike the canonical EF-Tu molecule that participates in the standard protein biosynthesis systems, which basically recognizes all elongator tRNAs. EF-Tu2 specifically recognizes Ser-tRNA^Ser that lacks a D arm but has a short T arm. Our previous study led us to speculate the lack of the D arm may be essential for the tRNA recognition of EF-Tu2. However, here, we showed that the EF-Tu2 can bind to D arm-bearing Ser-tRNAs, in which the D–T arm interaction was weakened by the mutations. The ethylnitrosourea-modification interference assay showed that EF-Tu2 is unique, in that it interacts with the phosphate groups on the T stem on the side that is opposite to where canonical EF-Tu binds. The hydrolysis protection assay using several EF-Tu2 mutants then strongly suggests that seven C-terminal amino acid residues of EF-Tu2 are essential for its aminoacyl-tRNA-binding activity. Our results indicate that the formation of the nematode mitochondrial (mt) EF-Tu2/GTP/aminoacyl-tRNA ternary complex is probably supported by a unique interaction between the C-terminal extension of EF-Tu2 and the tRNA.     

A protein extension to shorten RNA: elongated elongation factor-Tu recognizes the D-arm of T-armless tRNAs in nematode mitochondria

Nematode mitochondria possess extremely truncated tRNAs. Of 22 tRNAs, 20 lack the entire T-arm. The T-arm is necessary for the binding of canonical tRNAs and EF (elongation factor)-Tu (thermo-unstable). The nematode mitochondrial translation system employs two different EF-Tu factors named EF-Tu1 and EF-Tu2. Our previous study showed that nematode Caenorhabditis elegans EF-Tu1 binds specifically to T-armless tRNA. C. elegans EF-Tu1 has a 57-amino acid C-terminal extension that is absent from canonical EF-Tu, and the T-arm-binding residues of canonical EF-Tu are not conserved. In this study, the recognition mechanism of T-armless tRNA by EF-Tu1 was investigated. Both modification interference assays and primer extension analysis of cross-linked ternary complexes revealed that EF-Tu1 interacts not only with the tRNA acceptor stem but also with the D-arm. This is the first example of an EF-Tu recognizing the D-arm of a tRNA. The binding activity of EF-Tu1 was impaired by deletion of only 14 residues from the C-terminus, indicating that the C-terminus of EF-Tu1 is required for its binding to T-armless tRNA. These results suggest that C. elegans EF-Tu1 recognizes the D-arm instead of the T-arm by a mechanism involving its C-terminal region. This study sheds light on the co-evolution of RNA and RNA-binding proteins in nematode mitochondria.     

Identification of thermodynamically relevant interactions between EF-Tu and backbone elements of tRNA

A set of 45 different tRNAs, each containing a single deoxynucleotide substitution covering the upper half of the molecule was used in conjunction with a high-throughput ribonuclease protection assay to investigate the thermodynamic role of 2' hydroxyl groups in stabilizing a complex with elongation factor Tu (EF-Tu) from Thermus thermophilus. Five distinct 2' hydroxyl groups were identified where substitution with a proton resulted in an approximately tenfold decrease in the binding affinity. The same five 2' hydroxyl groups reduced the affinity of the interaction with the nearly identical Thermus aquaticus EF-Tu. Four of these 2' hydroxyl groups were observed to form hydrogen bonds in a co-crystal structure of tRNA(Phe) and T. aquaticus EF-Tu, while the fifth 2' hydroxyl group can be associated with an intramolecular hydrogen bond in the tRNA. However, four additional hydrogen bonds to 2' hydroxyl groups observed in the crystal structure show no thermodynamic effect upon disruption. Some of these discrepancies may be reconciled based on the unbound structures of the protein and RNA.     

An evolutionary 'intermediate state' of mitochondrial translation systems found in Trichinella species of parasitic nematodes: co-evolution of tRNA and EF-Tu

EF-Tu delivers aminoacyl-tRNAs to ribosomes in the translation system. However, unusual truncations found in some animal mitochondrial tRNAs seem to prevent recognition by a canonical EF-Tu. We showed previously that the chromadorean nematode has two distinct EF-Tus, one of which (EF-Tu1) binds only to T-armless aminoacyl-tRNAs and the other (EF-Tu2) binds to D-armless Ser-tRNAs. Neither of the EF-Tus can bind to canonical cloverleaf tRNAs. In this study, by analyzing the translation system of enoplean nematode Trichinella species, we address how EF-Tus and tRNAs have evolved from the canonical structures toward those of the chromadorean translation system. Trichinella mitochondria possess three types of tRNAs: cloverleaf tRNAs, which do not exist in chromadorean nematode mitochondria; T-armless tRNAs; and D-armless tRNAs. We found two mitochondrial EF-Tu species, EF-Tu1 and EF-Tu2, in Trichinella britovi. T.britovi EF-Tu2 could bind to only D-armless Ser-tRNA, as Caenorhabditis elegans EF-Tu2 does. In contrast to the case of C.elegans EF-Tu1, however, T.britovi EF-Tu1 bound to all three types of tRNA present in Trichinella mitochondria. These results suggest that Trichinella mitochondrial translation system, and particularly the tRNA-binding specificity of EF-Tu1, could be an intermediate state between the canonical system and the chromadorean nematode mitochondrial system.     

Mutagenesis of glutamine 290 in Escherichia coli and mitochondrial elongation factor Tu affects interactions with mitochondrial aminoacyl-tRNAs and GTPase activity

Elongation factor Tu (EF-Tu) is responsible for the delivery of the aminoacyl-tRNAs (aa-tRNA) to the ribosome during protein synthesis. The primary sequence of domain II of EF-Tu is highly conserved. However, several residues thought to be important for aa-tRNA binding in this domain are not conserved between the mammalian mitochondrial and bacterial factors. One of these residues is located at position 290 (Escherichia coli numbering). Residue 290 is Gln in most of the prokaryotic factors but is conserved as Leu (L338) in the mammalian mitochondrial factors. This residue is in a loop contacting the switch II region of domain I in the GTP-bound structure. It also helps to form the binding pocket for the 5' end of the aa-tRNA in the ternary complex. In the present work, Leu338 was mutated to Gln (L338Q) in EF-Tu(mt). The complementary mutation was created at the equivalent position in E. coli EF-Tu (Q290L). EF-Tu(mt) L338Q functions as effectively as wild-type EF-Tu(mt) in poly(U)-directed polymerization with both prokaryotic and mitochondrial substrates and in ternary complex formation assays with E. coli aa-tRNA. However, the L338Q mitochondrial variant has a reduced affinity for mitochondrial Phe-tRNA(Phe). E. coli EF-Tu Q290L is more active in poly(U)-directed polymerization with both mitochondrial and prokaryotic substrates and has a higher GTPase activity in both the absence and presence of ribosomes. Surprisingly, while E. coli EF-Tu Q290L is more active in polymerization with mitochondrial Phe-tRNA(Phe), this variant has low activity in the formation of a stable ternary complex with mitochondrial aa-tRNA.     

Characterization of the interaction between the nucleotide exchange factor EF-Ts from nematode mitochondria and elongation factor Tu

Caenorhabditis elegans mitochondria have two elongation factor (EF)-Tu species, denoted EF-Tu1 and EF-Tu2. Recombinant nematode EF-Ts purified from Escherichia coli bound both of these molecules and also stimulated the translational activity of EF-Tu, indicating that the nematode EF-Ts homolog is a functional EF-Ts protein of mitochondria. Complexes formed by the interaction of nematode EF-Ts with EF-Tu1 and EF-Tu2 could be detected by native gel electrophoresis and purified by gel filtration. Although the nematode mitochondrial (mt) EF-Tu molecules are extremely unstable and easily form aggregates, native gel electrophoresis and gel filtration analysis revealed that EF-Tu·EF-Ts complexes are significantly more soluble. This indicates that nematode EF-Ts can be used to stabilize homologous EF-Tu molecules for experimental purposes. The EF-Ts bound to two eubacterial EF-Tu species (E.coli and Thermus thermophilus). Although the EF-Ts did not bind to bovine mt EF-Tu, it could bind to a chimeric nematode–bovine EF-Tu molecule containing domains 1 and 2 from bovine mt EF-Tu. Thus, the nematode EF-Ts appears to have a broad specificity for EF-Tu molecules from different species.     

Structural basis of the action of pulvomycin and GE2270 A on elongation factor Tu

Pulvomycin inhibits protein synthesis by preventing the formation of the ternary complex between elongation factor Tu (EF-Tu) x GTP and aa-tRNA. In this work, the crystal structure of Thermus thermophilus EF-Tu x pulvomycin in complex with the GTP analogue guanylyl imino diphosphate (GDPNP) at 1.4 A resolution reveals an antibiotic binding site extending from the domain 1-3 interface to domain 2, overlapping the domain 1-2-3 junction. Pulvomycin binding interferes with the binding of the 3'-aminoacyl group, the acceptor stem, and 5' end of tRNA. Only part of pulvomycin overlaps the binding site of GE2270 A, a domain 2-bound antibiotic of a structure unrelated to pulvomycin, which also hinders aa-tRNA binding. The structure of the T. thermophilus EF-Tu x GDPNP x GE2270 A complex at 1.6 A resolution shows that GE2270 A interferes with the binding of the 3'-aminoacyl group and part of the acceptor stem of aa-tRNA but not with the 5' end. Both compounds, pulvomycin more markedly, hinder the correct positioning of domain 1 over domains 2 and 3 that characterizes the active form of EF-Tu, while they affect the domain 1 switch regions that control the EF-Tu x GDP/GTP transitions in different ways. This work reveals how two antibiotics with different structures and binding modes can employ a similar mechanism of action.     

Identification and characterization of mammalian mitochondrial tRNA nucleotidyltransferases

The CCA-adding enzyme (ATP:tRNA adenylyltransferase or CTP:tRNA cytidylyltransferase (EC )) generates the conserved CCA sequence responsible for the attachment of amino acid at the 3' terminus of tRNA molecules. It was shown that enzymes from various organisms strictly recognize the elbow region of tRNA formed by the conserved D- and T-loops. However, most of the mammalian mitochondrial (mt) tRNAs lack consensus sequences in both D- and T-loops. To characterize the mammalian mt CCA-adding enzymes, we have partially purified the enzyme from bovine liver mitochondria and determined cDNA sequences from human and mouse dbESTs by mass spectrometric analysis. The identified sequences contained typical amino-terminal peptides for mitochondrial protein import and had characteristics of the class II nucleotidyltransferase superfamily that includes eukaryotic and eubacterial CCA-adding enzymes. The human recombinant enzyme was overexpressed in Escherichia coli, and its CCA-adding activity was characterized using several mt tRNAs as substrates. The results clearly show that the human mt CCA-adding enzyme can efficiently repair mt tRNAs that are poor substrates for the E. coli enzyme although both enzymes work equally well on cytoplasmic tRNAs. This suggests that the mammalian mt enzymes have evolved so as to recognize mt tRNAs with unusual structures.     

Interaction of mammalian mitochondrial elongation factor EF-Tu with guanine nucleotides

Elongation factor Tu (EF-Tu) promotes the binding of aminoacyl-tRNA (aa-tRNA) to the acceptor site of the ribosome. During the elongation cycle, EF-Tu interacts with guanine nucleotides, aa-tRNA and its nucleotide exchange factor (EF-Ts). Quantitative determination of the equilibrium dissociation constants that govern the interactions of mammalian mitochondrial EF-Tu (EF-Tu(mt)) with guanine nucleotides was the focus of the work reported here. Equilibrium dialysis with [3H]GDP was used to measure the equilibrium dissociation constant of the EF-Tu(mt) x GDP complex (K(GDP) = 1.0 +/- 0.1 microM). Competition of GTP with a fluorescent derivative of GDP (mantGDP) for binding to EF-Tu(mt) was used to measure the dissociation constant of the EF-Tu(mt) x GTP complex (K(GTP) = 18 +/- 9 microM). The analysis of these data required information on the dissociation constant of the EF-Tu(mt) x mantGDP complex (K(mGDP) = 2.0 +/- 0.5 microM), which was measured by equilibrium dialysis. Both K(GDP) and K(GTP) for EF-Tu(mt) are quite different (about two orders of magnitude higher) than the dissociation constants of the corresponding complexes formed by Escherichia coli EF-Tu. The forward and reverse rate constants for the association and dissociation of the EF-Tu(mt) x GDP complex were determined using the change in the fluorescence of mantGDP upon interaction with EF-Tu(mt). These values are in agreement with a simple equilibrium binding interaction between EF-Tu(mt) and GDP. The results obtained are discussed in terms of the recently described crystal structure of the EF-Tu(mt) x GDP complex.     

Effects of mutagenesis of residue 221 on the properties of bacterial and mitochondrial elongation factor EF-Tu

During protein biosynthesis, elongation factor Tu (EF-Tu) delivers aminoacyl-tRNA (aa-tRNA) to the A-site of ribosomes. This factor is highly conserved throughout evolution. However, several key residues differ between bacterial and mammalian mitochondrial EF-Tu (EF-Tu(mt)). One such residue is Ser221 (Escherichia coli numbering). This residue is conserved as a Ser or Thr in the bacterial factors but is present as Pro269 in EF-Tu(mt). Pro269 reorients the loop containing this residue and shifts the adjoining beta-strand in EF-Tu(mt) compared to that of E. coli EF-Tu potentially altering the binding pocket for the acceptor stem of the aa-tRNA. Pro269 was mutated to a serine residue (P269S) in EF-Tu(mt). For comparison, the complementary mutation was created at Ser221 in E. coli EF-Tu (S221P). The E. coli EF-Tu S221P variant is poorly expressed in E. coli and the majority of the molecules fail to fold into an active conformation. In contrast, EF-Tu(mt) P269S is expressed to a high level in E. coli. When corrected for the percentage of active molecules, both variants function as effectively as their respective wild-type factors in ternary complex formation using E. coli Phe-tRNA(Phe) and Cys-tRNA(Cys). They are also active in A-site binding and in vitro translation assays with E. coli Phe-tRNA(Phe). In addition, both variants are as active as their respective wild-type factors in ternary complex formation, A-site binding and in vitro translation assays using mitochondrial Phe-tRNA(Phe).     

The 51-63 base pair of tRNA confers specificity for binding by EF-Tu

Elongation factor Tu (EF-Tu) exhibits significant specificity for the different elongator tRNA bodies in order to offset its variable affinity to the esterified amino acid. Three X-ray cocrystal structures reveal that while most of the contacts with the protein involve the phosphodiester backbone of tRNA, a single hydrogen bond is observed between the Glu390 and the amino group of a guanine in the 51-63 base pair in the T-stem of tRNA. Here we show that the Glu390Ala mutation of Thermus thermophilus EF-Tu selectively destabilizes binding of those tRNAs containing a guanine at either position 51 or 63 and that mutagenesis of the 51-63 base pair in several tRNAs modulates their binding affinities to EF-Tu. A comparison of Escherichia coli tRNA sequences suggests that this specificity mechanism is conserved across the bacterial domain. While this contact is an important specificity determinant, it is clear that others remain to be identified.     

Identification of the residues involved in the unique serine specificity of Caenorhabditis elegans mitochondrial EF-Tu2

In canonical translation systems, the single elongation factor Tu (EF-Tu) recognizes all elongator tRNAs. However, in Caenorhabditis elegans mitochondria, two distinct EF-Tu species, EF-Tu1 and EF-Tu2, recognize 20 species of T armless tRNA and two species of D armless tRNA(Ser), respectively. We previously reported that C. elegans mitochondrial EF-Tu2 specifically recognizes the serine moiety of serylated-tRNA. In this study, to identify the critical residues for the serine specificity in EF-Tu2, several residues in the amino acid binding pocket of bacterial EF-Tu were systematically replaced with corresponding EF-Tu2 residues, and the mutants were analyzed for their specificity for esterified amino acids attached to tRNAs. In this way, we obtained a bacterial EF-Tu mutant that acquired serine specificity after the introduction of 10 EF-Tu2 residues into its amino acid binding pocket. C. elegans EF-Tu2 mutants lacking serine specificity were also created by replacing seven or eight residues with bacterial residues. Further stressing the importance of these residues, we found that they are almost conserved in EF-Tu2 sequences of closely related nematodes. Thus, these three approaches reveal the critical residues essential for the unique serine specificity of C. elegans mitochondrial EF-Tu2.     

Starvation-induced cleavage of the tRNA anticodon loop in Tetrahymena thermophila

Amino acid deprivation triggers dramatic physiological responses in all organisms, altering both the synthesis and destruction of RNA and protein. Here we describe, using the ciliate Tetrahymena thermophila, a previously unidentified response to amino acid deprivation in which mature transfer RNA (tRNA) is cleaved in the anticodon loop. We observed that anticodon loop cleavage affects a small fraction of most or all tRNA sequences. Accumulation of cleaved tRNA is temporally coordinated with the morphological and metabolic changes of adaptation to starvation. The starvation-induced endonucleolytic cleavage activity targets tRNAs that have undergone maturation by 5' and 3' end processing and base modification. Curiously, the majority of cleaved tRNAs lack the 3' terminal CCA nucleotides required for aminoacylation. Starvation-induced tRNA cleavage is inhibited in the presence of essential amino acids, independent of the persistence of other starvation-induced responses. Our findings suggest that anticodon loop cleavage may reduce the accumulation of uncharged tRNAs as part of a specific response induced by amino acid starvation.     

Undetected antisense tRNAs in mitochondrial genomes?

Background  

The hypothesis that both mitochondrial (mt) complementary DNA strands of tRNA genes code for tRNAs (sense-antisense coding) is explored. This could explain why mt tRNA mutations are 6.5 times more frequently pathogenic than in other mt sequences. Antisense tRNA expression is plausible because tRNA punctuation signals mt sense RNA maturation: both sense and antisense tRNAs form secondary structures potentially signalling processing. Sense RNA maturation processes by default 11 antisense tRNAs neighbouring sense genes. If antisense tRNAs are expressed, processed antisense tRNAs should have adapted more for translational activity than unprocessed ones. Four tRNA properties are examined: antisense tRNA 5′ and 3′ end processing by sense RNA maturation and its accuracy, cloverleaf stability and misacylation potential.     

Cleavage of tRNA precursors by the RNA subunit of E. coli ribonuclease P (M1 RNA) is influenced by 3''-proximal CCA in the substrates

tRNA precursor molecules that contain the CCA sequence found at the 3' termini of all mature tRNAs are cleaved in vitro more readily by M1 RNA, the catalytic subunit of E. coli RNAase P, than precursors that lack this sequence. The sensitivity to the CCA sequence is not apparent when precursors are cleaved by the reconstituted RNAase P holoenzyme that contains both M1 RNA and the protein subunit. These results have been obtained with monomeric precursor molecules encoded by the E. coli and human chromosomes and with three dimeric precursor molecules encoded by the bacteriophage T4 genome. The data are in agreement with previous results concerning T4 tRNA biosynthesis in vivo and show that the CCA sequence is important for the processing of precursors to tRNAs.     

Interaction of mitochondrial elongation factor Tu with aminoacyl-tRNA and elongation factor Ts

Elongation factor (EF) Tu promotes the binding of aminoacyl-tRNA (aa-tRNA) to the acceptor site of the ribosome. This process requires the formation of a ternary complex (EF-Tu.GTP.aa-tRNA). EF-Tu is released from the ribosome as an EF-Tu.GDP complex. Exchange of GDP for GTP is carried out through the formation of a complex with EF-Ts (EF-Tu.Ts). Mammalian mitochondrial EF-Tu (EF-Tu(mt)) differs from the corresponding prokaryotic factors in having a much lower affinity for guanine nucleotides. To further understand the EF-Tu(mt) subcycle, the dissociation constants for the release of aa-tRNA from the ternary complex (K(tRNA)) and for the dissociation of the EF-Tu.Ts(mt) complex (K(Ts)) were investigated. The equilibrium dissociation constant for the ternary complex was 18 +/- 4 nm, which is close to that observed in the prokaryotic system. The kinetic dissociation rate constant for the ternary complex was 7.3 x 10(-)(4) s(-)(1), which is essentially equivalent to that observed for the ternary complex in Escherichia coli. The binding of EF-Tu(mt) to EF-Ts(mt) is mutually exclusive with the formation of the ternary complex. K(Ts) was determined by quantifying the effects of increasing concentrations of EF-Ts(mt) on the amount of ternary complex formed with EF-Tu(mt). The value obtained for K(Ts) (5.5 +/- 1.3 nm) is comparable to the value of K(tRNA).