Functional anticodon architecture of human tRNALys3 includes disruption of intraloop hydrogen bonding by the naturally occurring amino acid modification, t6A

The structure of the human tRNA(Lys3) anticodon stem and loop domain (ASL(Lys3)) provides evidence of the physicochemical contributions of N6-threonylcarbamoyladenosine (t(6)A(37)) to tRNA(Lys3) functions. The t(6)A(37)-modified anticodon stem and loop domain of tRNA(Lys3)(UUU) (ASL(Lys3)(UUU)- t(6)A(37)) with a UUU anticodon is bound by the appropriately programmed ribosomes, but the unmodified ASL(Lys3)(UUU) is not [Yarian, C., Marszalek, M., Sochacka, E., Malkiewicz, A., Guenther, R., Miskiewicz, A., and Agris, P. F., Biochemistry 39, 13390-13395]. The structure, determined to an average rmsd of 1.57 +/- 0.33 A (relative to the mean structure) by NMR spectroscopy and restrained molecular dynamics, is the first reported of an RNA in which a naturally occurring hypermodified nucleoside was introduced by automated chemical synthesis. The ASL(Lys3)(UUU)-t(6)A(37) loop is significantly different than that of the unmodified ASL(Lys3)(UUU), although the five canonical base pairs of both ASL(Lys3)(UUU) stems are in the standard A-form of helical RNA. t(6)A(37), 3'-adjacent to the anticodon, adopts the form of a tricyclic nucleoside with an intraresidue H-bond and enhances base stacking on the 3'-side of the anticodon loop. Critically important to ribosome binding, incorporation of the modification negates formation of an intraloop U(33).A(37) base pair that is observed in the unmodified ASL(Lys3)(UUU). The anticodon wobble position U(34) nucleobase in ASL(Lys3)(UUU)-t(6)A(37) is significantly displaced from its position in the unmodified ASL and directed away from the codon-binding face of the loop resulting in only two anticodon bases for codon binding. This conformation is one explanation for ASL(Lys3)(UUU) tendency to prematurely terminate translation and -1 frame shift. At the pH 5.6 conditions of our structure determination, A(38) is protonated and positively charged in ASL(Lys3)(UUU)-t(6)A(37) and the unmodified ASL(Lys3)(UUU). The ionized carboxylic acid moiety of t(6)A(37) possibly neutralizes the positive charge of A(+)(38). The protonated A(+)(38) can base pair with C(32), but t(6)A(37) may weaken the interaction through steric interference. From these results, we conclude that ribosome binding cannot simply be an induced fit of the anticodon stem and loop, otherwise the unmodified ASL(Lys3)(UUU) would bind as well as ASL(Lys3)(UUU)-t(6)A(37). t(6)A(37) and other position 37 modifications produce the open, structured loop required for ribosomal binding.     

Role of modified nucleosides of yeast tRNAPhe in ribosomal binding

Naturally occurring nucleoside modifications are an intrinsic feature of transfer RNA (tRNA), and have been implicated in the efficiency, as well as accuracy-of codon recognition. The structural and functional contributions of the modified nucleosides in the yeast tRNA(Phe) anticodon domain were examined. Modified nucleosides were site-selectively incorporated, individually and in combinations, into the heptadecamer anticodon stem and loop domain, (ASL(Phe)). The stem modification, 5-methylcytidine, improved RNA thermal stability, but had a deleterious effect on ribosomal binding. In contrast, the loop modification, 1-methylguanosine, enhanced ribosome binding, but dramatically decreased thermal stability. With multiple modifications present, the global ASL stability was mostly the result of the individual contributions to the stem plus that to the loop. The effect of modification on ribosomal binding was not predictable from thermodynamic contributions or location in the stem or loop. With 4/5 modifications in the ASL, ribosomal binding was comparable to that of the unmodified ASL. Therefore, modifications of the yeast tRNA(Phe) anticodon domain may have more to do with accuracy of codon reading than with affinity of this tRNA for the ribosomal P-site. In addition, we have used the approach of site-selective incorporation of specific nucleoside modifications to identify 2'O-methylation of guanosine at wobble position 34 (Gm34) as being responsible for the characteristically enhanced chemical reactivity of C1400 in Escherichia coli 16S rRNA upon ribosomal footprinting of yeast tRNA(Phe). Thus, effective ribosome binding of tRNA(Phe) is a combination of anticodon stem stability and the correct architecture and dynamics of the anticodon loop. Correct tRNA binding to the ribosomal P-site probably includes interaction of Gm34 with 16S rRNA C1400.     

Protein environment of the sense codon of the template in the A site of the human ribosome as inferred from crosslinking to oligoribonucleotide derivatives

The protein environment of each nucleotide of the template codon located in the A site of the human ribosome was studied with UUCUCAA and UUUGUU derivatives containing a Phe codon (UUC and UUU, respectively) and a perfluoroarylazido group at U4, U5, or U6. The analogs were positioned in the ribosome with the use of tRNA(Phe), which is cognate to the UUC or UUU codon and directs it to the P site, bringing a modified codon in the A site with a modified nucleotide occupying position +4, +5, or +6 relative to the first nucleotide of the P-site codon. On irradiation of ribosome complexes with tRNA(Phe) and mRNA analogs with mild UV light, the analogs crosslinked predominantly to the 40S subunit, modifying the proteins to a greater extent than the rRNA. The 18S rRNA nucleotides crosslinking to the analogs were identified previously. Of the small-subunit proteins, S3 and S15 were the major targets of modification in all cases. The former was modified both in ternary complexes and in the absence of tRNA, and the latter, only in ternary complexes. The extent of crosslinking of mRNA analogs to S15 decreased when the modified nucleotide was shifted from position +4 to position +6. The results were collated with the data on ribosomal proteins located at the decoding site of the 70S ribosome, and conclusion was made that the protein environment of the A-site codon strikingly differs between bacterial and eukaryotic ribosomes.     

Nucleotides of 18S rRNA surrounding mRNA codons at the human ribosomal A, P, and E sites: a crosslinking study with mRNA analogs carrying an aryl azide group at either the uracil or the guanine residue

The 18S rRNA environment of the mRNA at the decoding site of human 80S ribosomes has been studied by cross-linking with derivatives of hexaribonucleotide UUUGUU (comprising Phe and Val codons) that carried a perfluorophenylazide group either at the N7 atom of the guanine or at the C5 atom of the 5'-terminal uracil residue. The location of the codons on the ribosome at A, P, or E sites has been adjusted by the cognate tRNAs. Three types of complexes have been obtained for each type derivative, namely, (1) codon UUU and Phe-tRNAPhe at the P site (codon GUU at the A site), (2) codon UUU and tRNAPhe at the P site and PheVal-tRNAVal at the A site, and (3) codon GUU and Val-tRNAVal at the P site (codon UUU at the E site). This allowed the placement of modified nucleotides of the mRNA analog at positions -3, +1, or +4 on the ribosome. Mild UV irradiation resulted in tRNA-dependent crosslinking of the mRNA analogs to the 18S rRNA. Nucleotide G961 crosslinked to mRNA position -3, nucleotide G1207 to position +1, and A1823 together with A1824 to position +4. All of these nucleotides are located in the most strongly conserved regions of the small subunit RNA structure, and correspond to nucleotides G693, G926, G1491, and A1492 of bacterial 16S rRNA. Three of them (with the exception of G1491) had been found earlier at the 70S ribosomal decoding site. The similarities and differences between the 16S and 18S rRNA decoding sites are discussed.     

The role of modifications in codon discrimination by tRNA(Lys)UUU

The natural modification of specific nucleosides in many tRNAs is essential during decoding of mRNA by the ribosome. For example, tRNA(Lys)(UUU) requires the modification N6-threonylcarbamoyladenosine at position 37 (t(6)A37), adjacent and 3' to the anticodon, to bind AAA in the A site of the ribosomal 30S subunit. Moreover, it can only bind both AAA and AAG lysine codons when doubly modified with t(6)A37 and either 5-methylaminomethyluridine or 2-thiouridine at the wobble position (mnm(5)U34 or s(2)U34). Here we report crystal structures of modified tRNA anticodon stem-loops bound to the 30S ribosomal subunit with lysine codons in the A site. These structures allow the rationalization of how modifications in the anticodon loop enable decoding of both lysine codons AAA and AAG.     

Molecular dynamics simulations of human tRNA Lys,3 UUU: the role of modified bases in mRNA recognition

Accuracy in translation of the genetic code into proteins depends upon correct tRNA-mRNA recognition in the context of the ribosome. In human tRNA(Lys,3)UUU three modified bases are present in the anticodon stem-loop--2-methylthio-N6-threonylcarbamoyladenosine at position 37 (ms2t6A37), 5-methoxycarbonylmethyl-2-thiouridine at position 34 (mcm5s2U34) and pseudouridine (psi) at position 39--two of which, ms2t6A37 and mcm5s2U34, are required to achieve wild-type binding activity of wild-type human tRNA(Lys,3)UUU [C. Yarian, M. Marszalek, E. Sochacka, A. Malkiewicz, R. Guenther, A. Miskiewicz and P. F. Agris (2000) Biochemistry, 39, 13390-13395]. Molecular dynamics simulations of nine tRNA anticodon stem-loops with different combinations of nonstandard bases were performed. The wild-type simulation exhibited a canonical anticodon stair-stepped conformation. The ms2t6 modification at position 37 is required for maintenance of this structure and reduces solvent accessibility of U36. Ms2t6A37 generally hydrogen bonds across the loop and may prevent U36 from rotating into solution. A water molecule does coordinate to psi39 most of the simulation time but weakly, as most of the residence lifetimes are <40 ps.     

Protein Environment of the Sense Codon of the Template in the A Site of the Human Ribosome as Inferred from Crosslinking to Oligoribonucleotide Derivatives

The protein environment of each nucleotide of the template codon located in the A site of the human ribosome was studied with UUCUCAA and UUUGUU derivatives containing a Phe codon (UUC and UUU, respectively) and a perfluoroarylazido group at U4, U5, or U6. The analogs were positioned in the ribosome with the use of tRNA^Phe, which is cognate to the UUC or UUU codon and directs it to the P site, bringing a modified codon in the A site with a modified nucleotide occupying position +4, +5, or +6 relative to the first nucleotide of the P-site codon. On irradiation of ribosome complexes with tRNA^Phe and mRNA analogs with mild UV light, the analogs crosslinked predominantly to the 40S subunit, modifying the proteins to a greater extent than the rRNA. The 18S rRNA nucleotides crosslinking to the analogs were identified previously. Of the small-subunit proteins, S3 and S15 were the major targets of modification in all cases. The former was modified both in ternary complexes and in the absence of tRNA, and the latter, only in ternary complexes. The extent of crosslinking of mRNA analogs to S15 decreased when the modified nucleotide was shifted from position +4 to position +6. The results were collated with the data on ribosomal proteins located at the decoding site of the 70S ribosome, and conclusion was made that the protein environment of the A-site codon strikingly differs between bacterial and eukaryotic ribosomes.     

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.     

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.     

Nucleotide modifications and tRNA anticodon-mRNA codon interactions on the ribosome

We have carried out molecular dynamics simulations of the tRNA anticodon and mRNA codon, inside the ribosome, to study the effect of the common tRNA modifications cmo(5)U34 and m(6)A37. In tRNA(Val), these modifications allow all four nucleotides to be successfully read at the wobble position in a codon. Previous data suggest that entropic effects are mainly responsible for the extended reading capabilities, but detailed mechanisms have remained unknown. We have performed a wide range of simulations to elucidate the details of these mechanisms at the atomic level and quantify their effects: extensive free energy perturbation coupled with umbrella sampling, entropy calculations of tRNA (free and bound to the ribosome), and thorough structural analysis of the ribosomal decoding center. No prestructuring effect on the tRNA anticodon stem-loop from the two modifications could be observed, but we identified two mechanisms that may contribute to the expanded decoding capability by the modifications: The further reach of the cmo(5)U34 allows an alternative outer conformation to be formed for the noncognate base pairs, and the modification results in increased contacts between tRNA, mRNA, and the ribosome.     

Accommodating the bacterial decoding release factor as an alien protein among the RNAs at the active site of the ribosome

The decoding release factor （RF） triggers termination of protein synthesis by functionally mimicking a tRNA to span the decoding centre and the peptidyl transferase centre （PTC） of the ribosome. Structurally, it must fit into a site crafted for a tRNA and surrounded by five other RNAs, namely the adjacent peptidyl tRNA carrying the completed polypeptide, the mRNA and the three rRNAs. This is achieved by extending a structural domain from the body of the protein that results in a critical conformational change allowing it to contact the PTC. A structural model of the bacterial termination complex with the accommodated RF shows that it makes close contact with the first, second and third bases of the stop codon in the mRNA with two separate loops of structure＂ the anticodon loop and the loop at the tip of helix orS. The anticodon loop also makes contact with the base following the stop codon that is known to strongly influence termination efficiency. It confirms the close contact of domain 3 of the protein with the key RNA structures of the PTC. The mRNA signal for termination includes sequences upstream as well as downstream of the stop codon, and this may reflect structural restrictions for specific combinations of tRNA and RF to be bound onto the ribosome together. An unbiased SELEX approach has been investigated as a tool to identify potential rRNA-binding contacts of the bacterial RF in its different binding conformations within the active centre of the ribosome.     

The effect of specific structural modification on the biological activity of E. coli arginine tRNA.

Escherichia coli arginine tRNA1 has been modified at position s2C32 with iodoacetamide and a spin labelled derivative. The small effects on the charging ability of tRNA by the modifiications suggest that the synthetase does not bind to the tRNA in this region of the anticodon loop before the anticodon. A ternary complex of elongation factor Tu, GTP and the modified Arg-tRNA, can be formed allowing future studies of enzymatic binding to the ribosome. Using the triplet binding assay the native Arg-tRNA1 decodes all 4 codons beginning with CG. The modified Arg-tRNA1 has a restricted decoding but the decoding pattern is still unusual according to the Wobble Hypothesis.     

Decoding the genome: a modified view

Transfer RNA’s role in decoding the genome is critical to the accuracy and efficiency of protein synthesis. Though modified nucleosides were identified in RNA 50 years ago, only recently has their importance to tRNA’s ability to decode cognate and wobble codons become apparent. RNA modifications are ubiquitous. To date, some 100 different posttranslational modifications have been identified. Modifications of tRNA are the most extensively investigated; however, many other RNAs have modified nucleosides. The modifications that occur at the first, or wobble position, of tRNA’s anticodon and those 3′-adjacent to the anticodon are of particular interest. The tRNAs most affected by individual and combinations of modifications respond to codons in mixed codon boxes where distinction of the third codon base is important for discriminating between the correct cognate or wobble codons and the incorrect near-cognate codons (e.g. AAA/G for lysine versus AAU/C asparagine). In contrast, other modifications expand wobble codon recognition, such as U·U base pairing, for tRNAs that respond to multiple codons of a 4-fold degenerate codon box (e.g. GUU/A/C/G for valine). Whether restricting codon recognition, expanding wobble, enabling translocation, or maintaining the messenger RNA, reading frame modifications appear to reduce anticodon loop dynamics to that accepted by the ribosome. Therefore, we suggest that anticodon stem and loop domain nucleoside modifications allow a limited number of tRNAs to accurately and efficiently decode the 61 amino acid codons by selectively restricting some anticodon–codon interactions and expanding others.