氨酰-tRNA合成酶对tRNA的识别

氨酰-tRNA合成酶(aaRS)与tRNA的相互作用保证了蛋白质生物合成的忠实性. 氨酰-tRNA合成酶对tRNA识别的专一性依赖于aaRS特定的催化结构域和tRNA分子特异的三级结构构象. 反密码子和接受茎(包括73位)在大多数aaRS对tRNA分子的识别过程中起着关键作用, 其他部位如可变口袋、可变(茎)环等, 甚至修饰核苷酸对于一些识别过程也有重要作用.     

Nucleotide correlations that suggest tertiary interactions in the TV-replacement loop-containing mitochondrial tRNAs of the nematodes, Caenorhabditis elegans and Ascaris suum.

In the predicted secondary structures of 20 of the 22 tRNAs encoded in mitochondrial DNA (mtDNA) molecules of the nematodes, Caenorhabditis elegans and Ascaris suum, the T psi C arm and variable loop are replaced with a loop of 6 to 12 nucleotides: the TV-replacement loop. From considerations of patterns of nucleotide correlations in the central regions of these tRNAs, it seems highly likely that tertiary interactions occur within five sets of binary and ternary combinations of nucleotides that correspond in location to nucleotides known to be involved in tertiary interactions in yeast tRNA(Phe) and other standard tRNAs. These observations are consistent with the nematode TV-replacement loop-containing mt-tRNAs being folded into a similar L-shaped functional form to that demonstrated for standard tRNAs, and for the bovine DHU (dihydrouridine) arm replacement-loop-containing mt-tRNA(Ser(AGY)). However, the apparent occurrence in nematode mt-tRNAs of tertiary bonds common to standard tRNAs contrasts with the situation in bovine mt-tRNA(Ser(AGY)) where the functional form is dependent on an almost unique set of tertiary interactions. Because three of the proposed conserved tertiary interactions in the nematode mt-tRNAs involve nucleotides that occur in the variable loop in standard tRNAs, it seems more likely that in nematode mt-tRNAs it is the T psi C arm rather than the variable loop that has undergone the greatest proportional decrease in nucleotide number.     

Analysis of magnesium, europium and lead binding sites in methionine initiator and elongator tRNAs by specific metal-ion-induced cleavages

The specificity of cleavages in yeast and lupin initiator and elongator methionine tRNAs induced by magnesium, europium and lead has been analysed and compared with known patterns of yeast tRNA(Phe) hydrolysis. The strong D-loop cleavages occur in methionine elongator tRNAs at similar positions and with comparable efficiency to those found in tRNA(Phe), while the sites of weak anticodon loop cuts, identical in methionine elongator tRNAs, differ from those found in tRNA(Phe). Methionine initiator tRNAs differ from their elongator counterparts: (a) they are cleaved in the D-loop with much lower efficiency; (b) they are cleaved in the variable loop which is completely resistant to hydrolysis in elongator tRNAs; (c) cleavages in the anticodon loop are stronger in initiator tRNAs and they are located mostly at the 5' side of the loop whereas in elongator tRNAs they occur mostly at the opposite, 3' side of the loop. The distinct pattern of the anticodon loop cleavages is considered to be related to different conformations of the anticodon loop in the two types of methionine tRNAs.     

Mechanism of the difference in the binding affinity of E. coli tRNAGln to glutaminyl-tRNA synthetase caused by noninterface nucleotides in variable loop

Aminoacyl-tRNA synthetases (ARSs) distinguish their cognate tRNAs from many other kinds of tRNAs, despite the very similar tertiary structures of tRNAs. Many researchers have supported the view that this recognition is achieved by intermolecular interactions between tRNA and ARS. However, one of the aptamers of Escherichia coli glutamine specific tRNA, var-AGGU, has a higher affinity to ARS than the wild-type, although the sequence difference only lies in the variable loop located on the opposite side of the binding interface with ARS. To understand the reason for the difference in affinity, we did molecular dynamics simulations on tRNAs and their complexes with ARS. We calculated the enthalpic and entropic contributions to the binding free energy with the molecular mechanics-Poisson-Boltzmann/surface area method and found that the entropic difference plays an important role in the difference in binding free energies. During the molecular dynamics simulations, dynamic rearrangements of hydrogen bonds occurred in the tertiary core region of the wild-type tRNA, whereas they were not observed in the free var-AGGU simulation. Since the internal mobility was suppressed upon complex formation with ARS, the entropy loss in the wild-type was larger than that of the aptamer. We therefore concluded that the sequence difference in the variable loop caused the difference in the internal mobility of the tertiary core region tRNAs and led to the difference in the affinity to ARS through the entropy term.     

Comparative study of the reactability of phosphoric acid residues in tRNA(Ser) and tRNA(Leu) from Thermus thermophilus

The reactivity of phosphates in the Thermus thermophilus tRNA(Ser) (GCU) and tRNA(Leu) (CAG) was studied using the ethylnitrosourea modification. It was shown that phosphates of nucleotides 58-60 (T loop), 20-22 (D loop), and 48 (at the junction of the variable and T stems) were poorly modified in both tRNAs. The most pronounced differences in the reactivity were observed for phosphates at the junctions of the variable stem with T-stem (47q, 49) and anticodon stem (45). This indicates differences in orientations of the long variable arm relative to the backbone in the tRNAs studied.     

Structure of transfer RNA molecules containing the long variable loop

A structure is proposed for the type II tRNA molecules containing the long variable loop and the tertiary base interactions here are compared with type I tRNAs having the short variable loop. The type II tRNAs are similar to the type I tRNAs in their tertiary base pairing interactions but differ from them generally by not having the tertiary base triples. The long variable loop, which is comprised of a helical stem and a loop at the end of it, emerges from the deep groove side of the dihydrouridine helix, and is tilted roughly 30° to the plane formed by the amino acid-pseudouridine and anticodon-dihydrouridine helices found in yeast tRNA^Phe. The fact that many of the type I tRNAs also lack the full compliment of base triples suggests that the tertiary base pairs may alone suffice to sustain the tRNA fold required for its biological function. The base triples and the variable loop appear to have little functional significance. The base type at position 9 is correlated with the number of base triples and G-C base pairs in the dihydrouridine stem.     

A unique tRNA intron in the variable loop of the extreme thermophile Thermofilum pendens and its possible evolutionary implications

We describe, for the first time, an intron that is located in the variable loop of a tRNA. It is 18 nucleotides long and occurs within a precursor tRNAGly from the extreme thermophile Thermofilum pendens. The variable loop is less critical for tRNA function than the anticodon arm where other class III introns occur. This raises the possibility that tRNAs with a large variable loop (type II) arose from those with a small variable loop (type I) by retaining a splicing-deficient intron.     

The contacts of yeast tRNA(Ser) with seryl-tRNA synthetase studied by footprinting experiments

Yeast tRNA(Ser) is a member of the class II tRNAs, whose characteristic is the presence of an extended variable loop. This additional structural feature raises questions about the recognition of these class II tRNAs by their cognate synthetase and the possibility of the involvement of the extra arm in the recognition process. A footprinting study of yeast tRNA(Ser) complexed with its cognate synthetase, yeast seryl-tRNA synthetase (an alpha 2 dimer), was undertaken. Chemical (ethylnitrosourea) and enzymatic (nucleases S1 and V1) probes were used in the experiments. A map of the contact points between the tRNA and the synthetase was established and results were analyzed with respect to a three-dimensional model of yeast tRNA(Ser). Regions in close vicinity with the synthetase are clustered on one face of tRNA. The extra arm, which is strongly protected from chemical modifications, appears as an essential part of the contact area. The anticodon triplet and a large part of the anticodon arm are, in contrast, still accessible to the probes when the complex is formed. These results are discussed in the context of the recognition of tRNAs in the aminoacylation reaction.     

Evolutionary coadaptation of the motif 2--acceptor stem interaction in the class II prolyl-tRNA synthetase system

Known crystal structures of class II aminoacyl-tRNA synthetases complexed to their cognate tRNAs reveal that critical acceptor stem contacts are made by the variable loop connecting the beta-strands of motif 2 located within the catalytic core of class II synthetases. To identify potential acceptor stem contacts made by Escherichia coli prolyl-tRNA synthetase (ProRS), an enzyme of unknown structure, we performed cysteine-scanning mutagenesis in the motif 2 loop. We identified an arginine residue (R144) that was essential for tRNA aminoacylation but played no role in amino acid activation. Cross-linking experiments confirmed that the end of the tRNA(Pro) acceptor stem is proximal to this motif 2 loop residue. Previous work had shown that the tRNA(Pro) acceptor stem elements A73 and G72 (both strictly conserved among bacteria) are important recognition elements for E. coli ProRS. We carried out atomic group "mutagenesis" studies at these two positions of E. coli tRNA(Pro) and determined that major groove functional groups at A73 and G72 are critical for recognition by ProRS. Human tRNA(Pro), which lacks these elements, is not aminoacylated by the bacterial enzyme. An analysis of chimeric tRNA(Pro) constructs showed that, in addition to A73 and G72, transplantation of the E. coli tRNA(Pro) D-domain was necessary and sufficient to convert the human tRNA into a substrate for the bacterial synthetase. In contrast to the bacterial system, base-specific acceptor stem recognition does not appear to be used by human ProRS. Alanine-scanning mutagenesis revealed that motif 2 loop residues are not critical for tRNA aminoacylation activity of the human enzyme. Taken together, our results illustrate how synthetases and tRNAs have coadapted to changes in protein-acceptor stem recognition through evolution.     

tRNA leucine identity and recognition sets

Transfer RNAs (tRNAs) are grouped into two classes based on the structure of their variable loop. In Escherichia coli, tRNAs from three isoaccepting groups are classified as type II. Leucine tRNAs comprise one such group. We used both in vivo and in vitro approaches to determine the nucleotides that are required for tRNA(Leu) function. In addition, to investigate the role of the tRNA fold, we compared the in vivo and in vitro characteristics of type I tRNA(Leu) variants with their type II counterparts.A minimum of six conserved tRNA(Leu) nucleotides were required to change the amino acid identity and recognition of a type II tRNA(Ser) amber suppressor from a serine to a leucine residue. Five of these nucleotides affect tRNA tertiary structure; the G15-C48 tertiary "Levitt base-pair" in tRNA(Ser) was changed to A15-U48; the number of nucleotides in the alpha and beta regions of the D-loop was changed to achieve the positioning of G18 and G19 that is found in all tRNA(Leu); a base was inserted at position 47n between the base-paired extra stem and the T-stem; in addition the G73 "discriminator" base of tRNA(Ser) was changed to A73. This minimally altered tRNA(Ser) exclusively inserted leucine residues and was an excellent in vitro substrate for LeuRS. In a parallel experiment, nucleotide substitutions were made in a glutamine-inserting type I tRNA (RNA(SerDelta); an amber suppressor in which the tRNA(Ser) type II extra-stem-loop is replaced by a consensus type I loop). This "type I" swap experiment was successful both in vivo and in vitro but required more nucleotide substitutions than did the type II swap. The type I and II swaps revealed differences in the contributions of the tRNA(Leu) acceptor stem base-pairs to tRNA(Leu) function: in the type I, but not the type II fold, leucine specificity was contingent on the presence of the tRNA(Leu) acceptor stem sequence. The type I and II tRNAs used in this study differed only in the sequence and structure of the variable loop. By altering this loop, and thereby possibly introducing subtle changes into the overall tRNA fold, it became possible to detect otherwise cryptic contributions of the acceptor stem sequence to recognition by LeuRS. Possible reasons for this effect are discussed.     

Comparison of dissimilarity patterns of E coli, yeast and mammalian tRNAs.

A number of experimental approaches have been developed for identification of recognition (identity) sites in tRNAs. Along with them a theoretical methodology has been proposed by McClain et al that is based on concomitant analysis of all tRNA sequences from a given species. This approach allows an evaluation of nucleotide combinations present in isoacceptor tRNAs specific for the given amino acid, and not present in equivalent positions in cloverleaf structure in other tRNAs of the same organism. These elements predicted from computer analysis of the databank could be tested experimentally for their participation in forming recognition sites. The correlation between theoretical predictions and experimental data appeared promising. The aim of the present work consisted of introducing further improvements into McClain's procedure by: i), introducing into analysis a variable region in tRNAs which had not been previously considered; to accomplish this, 'normalization' of variable nucleotides was suggested, based on primary and tertiary structures of tRNAs; ii), developing a new procedure for comparison of patterns for synonymous and non-synonymous tRNAs from different organisms; iii), analysis of 3- and 4-positional contacts between tRNAs and enzymes in addition to a formerly used 2-positional model. A systematic application of McClain's procedure to mammalian, yeast and E coli tRNAs led to the following results: i), imitancy patterns for non-synonymous tRNAs of any amino acid specificity and from any organisms analysed so far overlap by no more than 30%, providing a structural basis for discrimination with high fidelity between cognate and non-cognate tRNAs; ii), the predicted identity sites are non-randomly distributed within tRNA molecules; the dominant role is ascribed to only two regions--anticodon and amino acid stem which are located far apart from one another at extremes of all tRNA molecules; iii), the imitancy patterns for synonymous tRNAs in lower (yeast) and higher (mammalian) eukaryotes are similar but not identical; iv), distribution of predicted identity sites in the cloverleaf structure in prokaryotes and eukaryotes is essentially different: in eubacterial tRNAs the major role in recognition plays anticodon and/or amino acid acceptor stem, whereas in eukaryotic (both unicellular and multicellular) tRNAs the remaining part of the molecules is also involved in recognition; v), the imitancy patterns of synonymous tRNAs from prokaryotes and eukaryotes are dissimilar, this observation leads to the prediction that the tRNA identity sites for the same amino acid in prokaryotes and eukaryotes may differ.     

Position 34 of tRNA is a discriminative element for m5C38 modification by human DNMT2

Dnmt2, a member of the DNA methyltransferase superfamily, catalyzes the formation of 5-methylcytosine at position 38 in the anticodon loop of tRNAs. Dnmt2 regulates many cellular biological processes, especially the production of tRNA-derived fragments and intergenerational transmission of paternal metabolic disorders to offspring. Moreover, Dnmt2 is closely related to human cancers. The tRNA substrates of mammalian Dnmt2s are mainly detected using bisulfite sequencing; however, we lack supporting biochemical data concerning their substrate specificity or recognition mechanism. Here, we deciphered the tRNA substrates of human DNMT2 (hDNMT2) as tRNA^Asp(GUC), tRNA^Gly(GCC) and tRNA^Val(AAC). Intriguingly, for tRNA^Asp(GUC) and tRNA^Gly(GCC), G34 is the discriminator element; whereas for tRNA^Val(AAC), the inosine modification at position 34 (I34), which is formed by the ADAT2/3 complex, is the prerequisite for hDNMT2 recognition. We showed that the C³²U³³(G/I)³⁴N³⁵ (C/U)³⁶A³⁷C³⁸ motif in the anticodon loop, U11:A24 in the D stem, and the correct size of the variable loop are required for Dnmt2 recognition of substrate tRNAs. Furthermore, mammalian Dnmt2s possess a conserved tRNA recognition mechanism.     

Mitochondrial tRNAs as light strand replication origins: Similarity between anticodon loops and the loop of the light strand replication origin predicts initiation of DNA replication

Stem-loop hairpins formed by mitochondrial light strand replication origins (OL) and by heavy strand DNA coding for tRNAs that form OL-like structures initiate mitochondrial replication. The loops are recognized by one of the two active sites of the vertebrate mitochondrial gamma polymerase, which are homologuous to the active sites of class II amino-acyl tRNA synthetases. Therefore, the polymerase site recognizing the OL loop could recognize tRNA anticodon loops and sequence similarity between anticodon and OL loops should predict initiation of DNA replication at tRNAs. Strengths of genome-wide deamination gradients starting at tRNA genes estimate extents by which replication starts at that tRNA. Deaminations (A→G and C→T) occur proportionally to time spent single stranded by heavy strand DNA during mitochondrial light strand replication. Results show that deamination gradients starting at tRNAs are proportional to sequence similarity between OL and tRNA loops: most for anticodon-, least D-, intermediate for TψC-loops, paralleling tRNA synthetase recognition interactions with these tRNA loops. Structural and sequence similarities with regular OLs predict OL function, loop similarity is dominant in most tRNAs. Analyses of sequence similarity and structure independently substantiate that DNA sequences coding for mitochondrial tRNAs sometimes function as alternative OLs. Pathogenic mutations in anticodon loops increase similarity with the human OL loop, non-pathogenic polymorphisms do not. Similarity/homology alignment hypotheses are experimentally testable in this system.     

Interaction of tRNAs with the ribosome at the A and P sites.

In vitro transcribed tRNA(Phe) analogues from Escherichia coli containing up to four randomly distributed A, G, U or C phosphorothioated nucleotides were used to investigate contact patterns with the ribosome in the A and P sites. The tRNAs were biologically active. Molecular iodine (I2) can trigger a break in the sugar-phosphate backbone at phosphorothioated positions of the ribosomal bound tRNAs if contacts with ribosomal components do not prevent access of the iodine. Highly differentiated protection patterns were found which were strikingly different in the A and P sites, respectively. Strong protections accumulated in the T psi C loop and no protection was seen in the extra-arm region in both sites, whereas the phosphates in the anticodon loop are more strongly protected in the A site. Strong common protections in both the A and P sites were found neighbouring universally or semi-universally conserved bases in prominent regions of the tertiary structure of tRNAs: Y11, Y32, U33, psi55, C56, A58 and Y60. These bases are therefore candidates for 'identity elements' in ribosomal tRNA recognition. The data further indicate that tRNAs change their conformations upon binding to either ribosomal site.     

tRNA recognition by tRNA-guanine transglycosylase from Escherichia coli: the role of U33 in U-G-U sequence recognition.

In eubacteria, the biosynthesis of queuine, a modified base found in the wobble position (#34) of tRNAs coding for Tyr, His, Asp, and Asn, occurs via a multistep pathway. One of the key enzymes in this pathway, tRNA-guanine transglycosylase (TGT), exchanges the genetically encoded guanine at position 34 with a queuine precursor, preQ1. Previous studies have identified a minimal positive RNA recognition motif for Escherichia coli TGT consisting of a stable minihelix that contains a U-G-U sequence starting at the second position of its seven base anticodon loop. Recently, we reported that TGT was capable of recognizing the U-G-U sequence outside of this limited structural context. To further characterize the ability of TGT to recognize the U-G-U sequence in alternate contexts, we constructed mutants of the previously characterized E. coli tRNA(Tyr) minihelix. The U-G-U sequence was shifted to various positions within the anticodon loop of these mutants. Characterization of these analogs demonstrates that in addition to the normal U33G34U35 position, TGT can also recognize the U34G35U36 analog (UGU(+1)). The other analogs were not active. This indicates that the recognition of the U-G-U sequence is not strictly dependent upon its position relative to the stem. In E. coli, the full-length tRNA with a U34G35U36 anticodon sequence is one of the isoacceptors that codes for threonine. We found that TGT is able to recognize tRNA(Thr(UGU)) but only in the absence of a uridine at position 33. U33, an invariant base present in all tRNAs, has been shown to strongly influence the conformation of the anticodon loop of certain tRNAs. We find that mutation of this base confers on TGT the ability to recognize U34G35U36, and suggests that loop conformation affects recognition. The fact that the other analogs were not active indicates that although TGT is capable of recognizing the U-G-U sequence in additional contexts, this recognition is not indiscriminate.     

Mechanisms of molecular recognition of tRNAs by aminoacyl-tRNA synthetases.

Interactions of Escherichia coli isoleucyl- and glutamyl-tRNA synthetases and their cognate tRNAs were analyzed by phosphate-alkylation mapping with N-nitroso-N-ethylurea and/or by 1H-NMR analysis. When E. coli tRNA(Ile) was bound with isoleucyl-tRNA synthetase, many of the phosphate groups in the anticodon loop and stem and in the D-stem were protected from alkylation. This result is consistent with that of analysis of imino proton resonances due to the secondary and tertiary base pairs. These analyses also suggested that the L-shaped tertiary structure of tRNA(Ile) is distorted upon complex formation with IleRS because of disruption of some tertiary base pairs. In the case of E. coli tRNA(Glu), several phosphate groups in the D-stem and the variable loop were significantly protected by the cognate synthetase. These results indicate that the two tRNAs, unlike other tRNAs studied so far, have some of the "identity determinants" in the D-stem and/or in the anticodon stem.     

Models for two tRNAs bound to successive codons on mRNA on the ribosome

We have investigated the structural changes necessary to build a model complex of two molecules of phenylalanine transfer RNA (tRNA(Phe) bound to successive codons in a short segment of a model messenger RNA (mRNA), consisting of U6. We keep the mRNA in an ideal helical conformation, deforming the tRNAs as necessary to eliminate steric overlaps while bringing the two 3' termini together. The resulting model has the two tRNAs oriented relative to one another in a manner that is very similar to a model developed by McDonald and Rein (1) in which the tRNAs maintain their ideal crystallographic conformations and all of the deformations are introduced into the mRNA. Consequently, regardless of how one divides the deformations between the tRNAs and the mRNA it is clear that, on the ribosome, the tRNA in the P site has its "front" side (that side with the variable loop) close to the "back" side of the tRNA in the A site (that side with the D loop). The space between the two molecules must be left free on the ribosome, in order to facilitate the transition from the A site to the P site. A detailed pathway is also proposed for changing the anticodon loop structure from that of the A site to that of the P site. The anticodon loop is always kept in a 3'-stacked conformation, since we find that the shift between the 3'-stacked and 5'-stacked structures proposed by Woese (2) is not feasible.