Crystal structure of a novel JmjC-domain-containing protein, TYW5, involved in tRNA modification

Wybutosine (yW) is a hypermodified nucleoside found in position 37 of tRNA^Phe, and is essential for correct phenylalanine codon translation. yW derivatives widely exist in eukaryotes and archaea, and their chemical structures have many species-specific variations. Among them, its hydroxylated derivative, hydroxywybutosine (OHyW), is found in eukaryotes including human, but the modification mechanism remains unknown. Recently, we identified a novel Jumonji C (JmjC)-domain-containing protein, TYW5 (tRNA yW-synthesizing enzyme 5), which forms the OHyW nucleoside by carbon hydroxylation, using Fe(II) ion and 2-oxoglutarate (2-OG) as cofactors. In this work, we present the crystal structures of human TYW5 (hTYW5) in the free and complex forms with 2-OG and Ni(II) ion at 2.5 and 2.8 Å resolutions, respectively. The structure revealed that the catalytic domain consists of a β-jellyroll fold, a hallmark of the JmjC domains and other Fe(II)/2-OG oxygenases. hTYW5 forms a homodimer through C-terminal helix bundle formation, thereby presenting a large, positively charged patch involved in tRNA binding. A comparison with the structures of other JmjC-domain-containing proteins suggested a mechanism for substrate nucleotide recognition. Functional analyses of structure-based mutants revealed the essential Arg residues participating in tRNA recognition by TYW5. These findings extend the repertoire of the tRNA modification enzyme into the Fe(II)/2-OG oxygenase superfamily.     

Biosynthesis of wybutosine, a hyper-modified nucleoside in eukaryotic phenylalanine tRNA

Wybutosine (yW) is a tricyclic nucleoside with a large side chain found at the 3'-position adjacent to the anticodon of eukaryotic phenylalanine tRNA. yW supports codon recognition by stabilizing codon-anticodon interactions during decoding on the ribosome. To identify genes responsible for yW synthesis from uncharacterized genes of Saccharomyces cerevisiae, we employed a systematic reverse genetic approach combined with mass spectrometry ('ribonucleome analysis'). Four genes YPL207w, YML005w, YGL050w and YOL141w (named TYW1, TYW2, TYW3 and TYW4, respectively) were essential for yW synthesis. Mass spectrometric analysis of each modification intermediate of yW revealed its sequential biosynthetic pathway. TYW1 is an iron-sulfur (Fe-S) cluster protein responsible for the tricyclic formation. Multistep enzymatic formation of yW from yW-187 could be reconstituted in vitro using recombinant TYW2, TYW3 and TYW4 with S-adenosylmethionine, suggesting that yW synthesis might proceed through sequential reactions in a complex formed by multiple components assembled with the precursor tRNA. This hypothesis is also supported by the fact that plant ortholog is a large fusion protein consisting of TYW2 and TYW3 with the C-terminal domain of TYW4.     

Structural basis of tRNA modification with CO2 fixation and methylation by wybutosine synthesizing enzyme TYW4

Wybutosine (yW), one of the most complicated modified nucleosides, is found in the anticodon loop of eukaryotic phenylalanine tRNA. This hypermodified nucleoside ensures correct codon recognition by stabilizing codon-anticodon pairings during the decoding process in the ribosome. TYW4 is an S-adenosylmethionine (SAM)-dependent enzyme that catalyzes the final step of yW biosynthesis, methylation and methoxycarbonylation. However, the structural basis for the catalytic mechanism by TYW4, and especially that for the methoxycarbonylation, have remained elusive. Here we report the apo and cofactor-bound crystal structures of yeast TYW4. The structures revealed that the C-terminal domain folds into a β-propeller structure, forming part of the binding pocket for the target nucleoside. A comparison of the apo, SAM-bound, and S-adenosylhomocysteine-bound structures of TYW4 revealed a drastic structural change upon cofactor binding, which may sequester solvent from the catalytic site during the reaction and facilitate product release after the reaction. In conjunction with the functional analysis, our results suggest that TYW4 catalyzes both methylation and methoxycarbonylation at a single catalytic site, and in the latter reaction, the methoxycarbonyl group is formed through the fixation of carbon dioxide.     

Pyruvate is the source of the two carbons that are required for formation of the imidazoline ring of 4-demethylwyosine

TYW1 catalyzes the condensation of N-methylguanosine with two carbon atoms from an unknown second substrate to form 4-demethylwyosine, which is a common intermediate in the biosynthesis of all of the hypermodified RNA bases related to wybutosine found in eukaryal and archaeal tRNA(Phe). Of the potential substrates examined, only incubation with pyruvate resulted in formation of 4-demethylwyosine. Moreover, incubation with C1, C2, C3, or C1,2,3-(13)C-labeled pyruvate showed that C2 and C3 are incorporated while C1 is not. The mechanistic implications of these results are discussed in the context of the structure of TYW1.     

Effect of conformational features on the aminoacylation of tRNAs and consequences on the permutation of tRNA specificities.

The structure and function of in vitro transcribed tRNA(Asp) variants with inserted conformational features characteristic of yeast tRNA(Phe), such as the length of the variable region or the arrangement of the conserved residues in the D-loop, have been investigated. Although they exhibit significant conformational alterations as revealed by Pb2+ treatment, these variants are still efficiently aspartylated by yeast aspartyl-tRNA synthetase. Thus, this synthetase can accommodate a variety of tRNA conformers. In a second series of variants, the identity determinants of yeast tRNA(Phe) were transplanted into the previous structural variants of tRNA(Asp). The phenylalanine acceptance of these variants improves with increasing the number of structural characteristics of tRNA(Phe), suggesting that phenylalanyl-tRNA synthetase is sensitive to the conformational frame embedding the cognate identity nucleotides. These results contrast with the efficient transplantation of tRNA(Asp) identity elements into yeast tRNA(Phe). This indicates that synthetases respond differently to the detailed conformation of their tRNA substrates. Efficient aminoacylation is not only dependent on the presence of the set of identity nucleotides, but also on a precise conformation of the tRNA.     

Permanent dipole moment of tRNA''s and variation of their structure in solution.

The structure of six different tRNA molecules has been analyzed in solution by electrooptical measurements and by bead model simulations. The electric dichroism measured as a function of the field strength shows that tRNA's are associated with substantial permanent dipole moments, which are in the range of 1 x 10(-27) cm(identical to 300 D; before correction for the internal directing field). Rotational diffusion time constants of tRNA molecules in their native state at 2 degrees C show a considerable variation. A particularly large value found for tRNA(Tyr) (50 ns) can be explained by its nine additional nucleotide residues. However, remarkable variations remain for tRNA molecules with the standard number of 76 nucleotide residues (tRNA(Phe) [yeast] 41.6 ns, tRNA(Val) [Escherichia coli] 44.9 ns, tRNA(Glu) [E. coli] 46.8 ns; tRNA(Phe) [E. coli] 48.3 ns). These variations indicate modulations of the tertiary structure, which may be due to a change of the L-hinge angle. Bead models are used to simulate both electric and hydrodynamic parameters of tRNA molecules according to the crystal structure of tRNA(Phe) (yeast). The asymmetric distribution of phosphate charges with respect to the center of diffusion leads, under the assumption of a constant charge reduction to 15% by ion condensation, to a theoretical dipole moment of 7.2 x 10(-28) cm, which is in reasonable agreement with the measurements. The dichroism decay curve calculated for tRNA(Phe) (yeast) is also consistent with the measurements and thus the structure in solution and in the crystal must be very similar in this case. However, our measurements also indicate that the structure of some other tRNA's in solution is different, even in cases with the same number of nucleotide residues.     

The nature of the modification at position 37 of tRNAPhe correlates with acquired taxol resistance

Acquired drug resistance is a major obstacle in cancer therapy. Recent studies revealed that reprogramming of tRNA modifications modulates cancer survival in response to chemotherapy. However, dynamic changes in tRNA modification were not elucidated. In this study, comparative analysis of the human cancer cell lines and their taxol resistant strains based on tRNA mapping was performed by using UHPLC–MS/MS. It was observed for the first time in all three cell lines that 4-demethylwyosine (imG-14) substitutes for hydroxywybutosine (OHyW) due to tRNA-wybutosine synthesizing enzyme-2 (TYW2) downregulation and becomes the predominant modification at the 37^th position of tRNA^phe in the taxol-resistant strains. Further analysis indicated that the increase in imG-14 levels is caused by downregulation of TYW2. The time courses of the increase in imG-14 and downregulation of TYW2 are consistent with each other as well as consistent with the time course of the development of taxol-resistance. Knockdown of TYW2 in HeLa cells caused both an accumulation of imG-14 and reduction in taxol potency. Taken together, low expression of TYW2 enzyme promotes the cancer survival and resistance to taxol therapy, implying a novel mechanism for taxol resistance. Reduction of imG-14 deposition offers an underlying rationale to overcome taxol resistance in cancer chemotherapy.     

Identification of critical residues for G-1 addition and substrate recognition by tRNA(His) guanylyltransferase

The yeast tRNA(His) guanylyltransferase (Thg1) is an essential enzyme in yeast. Thg1 adds a single G residue to the 5' end of tRNA(His) (G(-1)), which serves as a crucial determinant for aminoacylation of tRNA(His). Thg1 is the only known gene product that catalyzes the 3'-5' addition of a single nucleotide via a normal phosphodiester bond, and since there is no identifiable sequence similarity between Thg1 and any other known enzyme family, the mechanism by which Thg1 catalyzes this unique reaction remains unclear. We have altered 29 highly conserved Thg1 residues to alanine, and using three assays to assess Thg1 catalytic activity and substrate specificity, we have demonstrated that the vast majority of these highly conserved residues (24/29) affect Thg1 function in some measurable way. We have identified 12 Thg1 residues that are critical for G(-1) addition, based on significantly decreased ability to add G(-1) to tRNA(His) in vitro and significant defects in complementation of a thg1Delta yeast strain. We have also identified a single Thg1 alteration (D68A) that causes a dramatic decrease in the rigorous specificity of Thg1 for tRNA(His). This single alteration enhances the k(cat)/K(M) for ppp-tRNA(Phe) by nearly 100-fold relative to that of wild-type Thg1. These results suggest that Thg1 substrate recognition is at least in part mediated by preventing recognition of incorrect substrates for nucleotide addition.     

Crystal structure of the radical SAM enzyme catalyzing tricyclic modified base formation in tRNA

Wyosine and its derivatives, such as wybutosine, found in eukaryotic and archaeal tRNAs, are tricyclic hypermodified nucleosides. In eukaryotes, wybutosine exists exclusively in position 37, 3'-adjacent to the anticodon, of tRNA(Phe), where it ensures correct translation by stabilizing the codon-anticodon base-pairing during the ribosomal decoding process. Recent studies revealed that the wyosine biosynthetic pathway consists of multistep enzymatic reactions starting from a guanosine residue. Among these steps, TYW1 catalyzes the second step to form the tricyclic ring structure, by cyclizing N(1)-methylguanosine. In this study, we solved the crystal structure of TYW1 from Methanocaldococcus jannaschii at 2.4 A resolution. TYW1 assumes an incomplete TIM barrel with (alpha/beta)(6) topology, which closely resembles the reported structures of radical SAM enzymes. Hence, TYW1 was considered to catalyze the cyclization reaction by utilizing the radical intermediate. Comparison with other radical SAM enzymes allowed us to build a model structure complexed with S-adenosylmethionine and two [4Fe-4S] clusters. Mutational analyses in yeast supported the validity of this complex model structure, which provides a structural insight into the radical reaction involving two [4Fe-4S] clusters to create a complex tricyclic base.     

Orientation of the tRNA anticodon in the ribosomal P-site: quantitative footprinting with U33-modified, anticodon stem and loop domains.

Binding of transfer RNA (tRNA) to the ribosome involves crucial tRNA-ribosomal RNA (rRNA) interactions. To better understand these interactions, U33-substituted yeast tRNA(Phe) anticodon stem and loop domains (ASLs) were used as probes of anticodon orientation on the ribosome. Orientation of the anticodon in the ribosomal P-site was assessed with a quantitative chemical footprinting method in which protection constants (Kp) quantify protection afforded to individual 16S rRNA P-site nucleosides by tRNA or synthetic ASLs. Chemical footprints of native yeast tRNA(Phe), ASL-U33, as well as ASLs containing 3-methyluridine, cytidine, or deoxyuridine at position 33 (ASL-m3U33, ASL-C33, and ASL-dU33, respectively) were compared. Yeast tRNAPhe and the ASL-U33 protected individual 16S rRNA P-site nucleosides differentially. Ribosomal binding of yeast tRNA(Phe) enhanced protection of C1400, but the ASL-U33 and U33-substituted ASLs did not. Two residues, G926 and G1338 with KpS approximately 50-60 nM, were afforded significantly greater protection by both yeast tRNA(Phe) and the ASL-U33 than other residues, such as A532, A794, C795, and A1339 (KpS approximately 100-200 nM). In contrast, protections of G926 and G1338 were greatly and differentially reduced in quantitative footprints of U33-substituted ASLs as compared with that of the ASL-U33. ASL-m3U33 and ASL-C33 protected G530, A532, A794, C795, and A1339 as well as the ASL-U33. However, protection of G926 and G1338 (KpS between 70 and 340 nM) was significantly reduced in comparison to that of the ASL-U33 (43 and 61 nM, respectively). Though protections of all P-site nucleosides by ASL-dU33 were reduced as compared to that of the ASL-U33, a proportionally greater reduction of G926 and G1338 protections was observed (KpS = 242 and 347 nM, respectively). Thus, G926 and G1338 are important to efficient P-site binding of tRNA. More importantly, when tRNA is bound in the ribosomal P-site, G926 and G1338 of 16S rRNA and the invariant U33 of tRNA are positioned close to each other.     

A conserved family of Saccharomyces cerevisiae synthases effects dihydrouridine modification of tRNA

Dihydrouridine modification of tRNA is widely observed in prokaryotes and eukaryotes, as well as in some archaea. In Saccharomyces cerevisiae every sequenced tRNA has at least one such modification, and all but one have two or more. We have used a biochemical genomics approach to identify the gene encoding dihydrouridine synthase 1 (Dus1, ORF YML080w), using yeast pre-tRNA(Phe) as a substrate. Dus1 is a member of a widespread family of conserved proteins, three other members of which are found in yeast: YNR015w, YLR405w, and YLR401c. We show that one of these proteins, Dus2, encoded by ORF YNR015w, has activity with two other substrates: yeast pre-tRNA(Tyr) and pre-tRNA(Leu). Both Dus1 and Dus2 are active as a single subunit protein expressed and purified from Escherichia coli, and the activity of both is stimulated in the presence of flavin adenine dinucleotide. Dus1 modifies yeast pre-tRNA(Phe) in vitro at U17, one of the two positions that are known to bear this modification in vivo. Yeast extract from a dus1-A strain is completely defective in modification of yeast pre-tRNAPhe, and RNA isolated from dus1-delta and dus2-delta strains is significantly depleted in dihydrouridine content.     

Conformational change of the L-shaped tRNA(Phe) molecule

Fluorophore of proflavine was introduced onto the 3'-terminal ribose moiety of yeast tRNA(Phe). The distance between the fluorophore and the fluorescent Y base in the anticodon of yeast tRNA(Phe) was measured by a singlet-singlet energy transfer. Conformational changes of tRNA(Phe) with binding of tRNA(2Glu), which has the anticodon UUC complementary to the anticodon GAA of tRNA(Phe), were investigated. The distance obtained at the ionic strength of 100 mM K+ and 10 mM Mg2+ is very close to the distance from x-ray diffraction, while the distance obtained in the presence of tRNA(2Glu) is significantly smaller. Further, using a fluorescent probe of 4-bromomethyl-7-methoxycoumarin introduced onto pseudouridine residue psi 55 in the T psi C loop of tRNA(Phe), Stern-Volmer quenching experiments for the probe with or without added tRNA(2Glu) were carried out. The results showed greater access of the probe to the quencher with added tRNA(2Glu). These results suggest that both arms of the L-shaped tRNA structure tend to bend inside with binding of tRNA(2Glu) and some structural collapse occurs at the corner of the L-shaped structure.     

Characterization of the lead(II)-induced cleavages in tRNAs in solution and effect of the Y-base removal in yeast tRNAPhe

The specificity of lead(II)-induced hydrolysis of yeast tRNA(Phe) was studied as a function of concentration of Pb2+ ions. The major cut was localized in the D-loop and minor cleavages were detected in the anticodon and T-loops at high metal ion concentration. The effects of pH, temperature, and urea were also analyzed, revealing a basically unchanged specificity of hydrolysis. In the isolated 5'-half-molecule of yeast tRNAPhe not cut was found in the D-loop, indicating its stringent dependence on T-D-loop interaction. Comparison of hydrolysis patterns and efficiencies observed in yeast tRNA(Phe) with those found in other tRNAs suggests that the presence of a U59-C60 sequence in the T-loop is responsible for the highly efficient and specific hydrolysis in the spatially close region of the D-loop. The efficiencies of D-loop cleavage in intact yeast tRNA(Phe) and in tRNA(Phe) deprived of the Y base next to the anticodon were also compared at various Pb2+ ion concentrations. Kinetics of the D-loop hydrolysis analyzed at 0, 25, and 37 degrees C showed a 6 times higher susceptibility of tRNA(Phe) minus Y base (tRNA(Phe)-Y) to lead(II)-induced hydrolysis than in tRNA(Phe). The observed effect is discussed in terms of a long-distance conformational transition in the region of the interacting D- and T-loops triggered by the Y-base excision.     

Tertiary structure of Escherichia coli tRNA(3Thr) in solution and interaction of this tRNA with the cognate threonyl-tRNA synthetase

The solution structure of Escherichia coli tRNA(3Thr) (anticodon GGU) and the residues of this tRNA in contact with the alpha 2 dimeric threonyl-tRNA synthetase were studied by chemical and enzymatic footprinting experiments. Alkylation of phosphodiester bonds by ethylnitrosourea and of N-7 positions in guanosines and N-3 positions in cytidines by dimethyl sulphate as well as carbethoxylation of N-7 positions in adenosines by diethyl pyrocarbonate were conducted on different conformers of tRNA(3Thr). The enzymatic structural probes were nuclease S1 and the cobra venom ribonuclease. Results will be compared to those of three other tRNAs, tRNA(Asp), tRNA(Phe) and tRNA(Trp), already mapped with these probes. The reactivity of phosphates towards ethylnitrosourea of the unfolded tRNA was compared to that of the native molecule. The alkylation pattern of tRNA(3Thr) shows some similarities to that of yeast tRNA(Phe) and mammalian tRNA(Trp), especially in the D-arm (positions 19 and 24) and with tRNA(Trp), at position 50, the junction between the variable region and the T-stem. In the T-loop, tRNA(3Thr), similarly to the three other tRNAs, shows protections against alkylation at phosphates 59 and 60. However, tRNA(3Thr) is unique as far as very strong protections are also found for phosphates 55 to 58 in the T-loop. Compared with yeast tRNA(Asp), the main differences in reactivity concern phosphates 19, 24 and 50. Mapping of bases with dimethyl sulphate and diethyl pyrocarbonate reveal conformational similarities with yeast tRNA(Phe). A striking conformational feature of tRNA(3Thr) is found in the 3'-side of its anticodon stem, where G40, surrounded by two G residues, is alkylated under native conditions, in contrast to other G residues in stem regions of tRNAs which are unreactive when sandwiched between two purines. This data is indicative of a perturbed helical conformation in the anticodon stem at the level of the 30-40 base pairs. Footprinting experiments, with chemical and enzymatic probes, on the tRNA complexed with its cognate threonyl-tRNA synthetase indicate significant protections in the anticodon stem and loop region, in the extra-loop, and in the amino acid accepting region. The involvement of the anticodon of tRNA(3Thr) in the recognition process with threonyl-tRNA synthetase was demonstrated by nuclease S1 mapping and by the protection of G34 and G35 against alkylation by dimethyl sulphate. These data are discussed in the light of the tRNA/synthetase recognition problem and of the structural and functional properties of the tRNA-like structure present in the operator region of the thrS mRNA.