tRNA-guanine transglycosylase from Escherichia coli: recognition of noncognate-cognate chimeric tRNA and discovery of a novel recognition site within the TpsiC arm of tRNA(Phe)

The human tRNA-guanine transglycosylase displays promiscuous nucleobase preference but strict tRNA specificity

Base-modification can occur throughout a transfer RNA molecule; however, elaboration is particularly prevalent at position 34 of the anticodon loop (the wobble position), where it functions to influence protein translation. Previously, we demonstrated that the queuosine modification at position 34 can be substituted with an artificial analogue via the queuine tRNA ribosyltransferase enzyme to induce disease recovery in an animal model of multiple sclerosis. Here, we demonstrate that the human enzyme can recognize a very broad range of artificial 7-deazaguanine derivatives for transfer RNA incorporation. By contrast, the enzyme displays strict specificity for transfer RNA species decoding the dual synonymous NAU/C codons, determined using a novel enzyme-RNA capture-release method. Our data highlight the broad scope and therapeutic potential of exploiting the queuosine incorporation pathway to intentionally engineer chemical diversity into the transfer RNA anticodon.

The role of intracellular compartmentalization on tRNA processing and modification

A signature of most eukaryotic cells is the presence of intricate membrane systems. Intracellular organization presumably evolved to provide order, and add layers for regulation of intracellular processes; compartmentalization also forcibly led to the appearance of sophisticated transport systems. With nucleus-encoded tRNAs, it led to the uncoupling of tRNA synthesis from many of the maturation steps it undergoes. It is now clear that tRNAs are actively transported across intracellular membranes and at any point, in any compartment, they can be post-transcriptionally modified; modification enzymes themselves may localize to any of the genome-containing compartments. In the following pages, we describe a number of well-known examples of how intracellular compartmentalization of tRNA processing and modification activities impact the function and fate of tRNAs. We raise the possibility that rates of intracellular transport may influence the level of modification and as such increase the diversity of differentially modified tRNAs in cells.

Fluorescent turn-on probes for wash-free mRNA imaging via covalent site-specific enzymatic labeling

Investigating the many roles RNA plays in cellular regulation and function has increased demand for tools to explore RNA tracking and localization within cells.

Investigating the many roles RNA plays in cellular regulation and function has increased demand for tools to explore RNA tracking and localization within cells. Our recently reported RNA-TAG (transglycosylation at guanine) approach uses an RNA-modifying enzyme, tRNA-guanine transglycosylase (TGT), to accomplish covalent labeling of an RNA of interest with fluorescent tracking agents in a highly selective and efficient manner. Unfortunately, labeling by this method currently suffers from a high nonspecific fluorescent background and is currently unsuitable for imaging RNA within complex cellular environments. Herein we report the design and synthesis of novel fluorogenic thiazole orange probes that significantly lower nonspecific binding and background fluorescence and, as a result, provide up to a 100-fold fluorescence intensity increase after labeling. Using these fluorogenic labeling agents, we were able to image mRNA expressed in Chinese Hamster Ovary cells in a wash-free manner.

Multisite-specific archaeosine tRNA-guanine transglycosylase (ArcTGT) from Thermoplasma acidophilum, a thermo-acidophilic archaeon

Archaeosine (G⁺), which is found only at position 15 in many archaeal tRNA, is formed by two steps, the replacement of the guanine base with preQ₀ by archaeosine tRNA-guanine transglycosylase (ArcTGT) and the subsequent modification of preQ₀ to G⁺ by archaeosine synthase. However, tRNA^Leu from Thermoplasma acidophilum, a thermo-acidophilic archaeon, exceptionally has two G⁺13 and G⁺15 modifications. In this study, we focused on the biosynthesis mechanism of G⁺13 and G⁺15 modifications in this tRNA^Leu. Purified ArcTGT from Pyrococcus horikoshii, for which the tRNA recognition mechanism and structure were previously characterized, exchanged only the G15 base in a tRNA^Leu transcript with ¹⁴C-guanine. In contrast, T. acidophilum cell extract exchanged both G13 and G15 bases. Because T. acidophilum ArcTGT could not be expressed as a soluble protein in Escherichia coli, we employed an expression system using another thermophilic archaeon, Thermococcus kodakarensis. The arcTGT gene in T. kodakarensis was disrupted, complemented with the T. acidophilum arcTGT gene, and tRNA^Leu variants were expressed. Mass spectrometry analysis of purified tRNA^Leu variants revealed the modifications of G⁺13 and G⁺15 in the wild-type tRNA^Leu. Thus, T. acidophilum ArcTGT has a multisite specificity and is responsible for the formation of both G⁺13 and G⁺15 modifications.

The queuine micronutrient: charting a course from microbe to man

Micronutrients from the diet and gut microbiota are essential to human health and wellbeing. Arguably, among the most intriguing and enigmatic of these micronutrients is queuine, an elaborate 7-deazaguanine derivative made exclusively by eubacteria and salvaged by animal, plant and fungal species. In eubacteria and eukaryotes, queuine is found as the sugar nucleotide queuosine within the anticodon loop of transfer RNA isoacceptors for the amino acids tyrosine, asparagine, aspartic acid and histidine. The physiological requirement for the ancient queuine molecule and queuosine modified transfer RNA has been the subject of varied scientific interrogations for over four decades, establishing relationships to development, proliferation, metabolism, cancer, and tyrosine biosynthesis in eukaryotes and to invasion and proliferation in pathogenic bacteria, in addition to ribosomal frameshifting in viruses. These varied effects may be rationalized by an important, if ill-defined, contribution to protein translation or may manifest from other presently unidentified mechanisms. This article will examine the current understanding of queuine uptake, tRNA incorporation and salvage by eukaryotic organisms and consider some of the physiological consequence arising from deficiency in this elusive and lesser-recognized micronutrient.

Probing the intermediacy of covalent RNA enzyme complexes in RNA modification enzymes

Within the large and diverse group of RNA-modifying enzymes, a number of enzymes seem to form stable covalent linkages to their respective RNA substrates. A complete understanding of the chemical and kinetic mechanisms of these enzymes, some of which have identified pathological roles, is lacking. As part of our ongoing work studying the posttranscriptional modification of tRNA with queuine, we wish to understand fully the chemical and kinetic mechanisms involved in this key transglycosylation reaction. In our previous investigations, we have used a gel mobility-shift assay to characterize an apparent covalent enzyme-RNA intermediate believed to be operative in the catalytic pathway. However, the simple observation of a covalent complex is not sufficient to prove intermediacy. To be a true intermediate, the complex must be both chemically and kinetically competent. As a case study for the proof of intermediacy, we report the use of this gel-shift assay under mildly denaturing conditions to probe the kinetic competency of the covalent association between RNA and the tRNA modifying enzyme tRNA-guanine transglycosylase (TGT).

Glycotargeting to improve cellular delivery efficiency of nucleic acids

Nucleic acids bearing glycans of various structures have been under vigorous investigation in the past decade. The carbohydrate moieties of such complexes can serve as recognition sites for carbohydrate-binding proteins-lectins-and initiate receptor-mediated endocytosis. Therefore, carbohydrates can enhance cell targeting and internalization of nucleic acids that are associated with them and thus improve the bioavailability of nucleic acids as therapeutic agents. This review summarizes nucleic acid glycosylation in nature and approaches for the preparation of both non-covalently associated and covalently-linked carbohydrate-nucleic acid complexes.

Sequence-specific recognition of colicin E5, a tRNA-targeting ribonuclease

Colicin E5 is a novel Escherichia coli ribonuclease that specifically cleaves the anticodons of tRNA(Tyr), tRNA(His), tRNA(Asn) and tRNA(Asp). Since this activity is confined to its 115 amino acid long C-terminal domain (CRD), the recognition mechanism of E5-CRD is of great interest. The four tRNA substrates share the unique sequence UQU within their anticodon loops, and are cleaved between Q (modified base of G) and 3' U. Synthetic minihelix RNAs corresponding to the substrate tRNAs were completely susceptible to E5-CRD and were cleaved in the same manner as the authentic tRNAs. The specificity determinant for E5-CRD was YGUN at -1 to +3 of the 'anticodon'. The YGU is absolutely required and the extent of susceptibility of minihelices depends on N (third letter of the anticodon) in the order A > C > G > U accounting for the order of susceptibility tRNA(Tyr) > tRNA(Asp) > tRNA(His), tRNA(Asn). Contrastingly, we showed that GpUp is the minimal substrate strictly retaining specificity to E5-CRD. The effect of contiguous nucleotides is inconsistent between the loop and linear RNAs, suggesting that nucleotide extension on each side of GpUp introduces a structural constraint, which is reduced by a specific loop structure formation that includes a 5' pyrimidine and 3' A.

Transglycosylation: a mechanism for RNA modification (and editing?)

The vast majority of the ca. 100 chemically distinct modified nucleosides in RNA appear to arise via the chemical transformation of a genetically encoded nucleoside. Two notable exceptions are queuosine and pseudouridine, which are incorporated into tRNA via transglycosylation. Transglycosylation is an extremely efficient process for incorporating highly modified bases such as queuine into RNA. Transglycosylation is also a requisite process for "isomerizing" an N-nucleoside into a C-nucleoside as is the case for pseudouridine formation. Finally, transglycosylation is an attractive possibility for certain RNA editing events (e.g., pyrimidine to purine conversions) that cannot occur via the known, more straightforward enzymatic reactions (e.g., deaminations). This review discusses what is known about the mechanisms of transglycosylation for the queuine and pseudouridine RNA modifications and will speculate about a potential role for transglycosylation in certain RNA editing events.

Substrate tRNA Recognition Mechanism of tRNA (m7G46) Methyltransferase from Aquifex aeolicus

Transfer RNA (m7G46) methyltransferase catalyzes the methyl transfer from S-adenosylmethionine to N7 atom of the guanine 46 residue in tRNA. Analysis of the Aquifex aeolicus genome revealed one candidate open reading frame, aq065, encoding this gene. The aq065 protein was expressed in Escherichia coli and purified to homogeneity on 15% SDS-polyacrylamide gel electrophoresis. Although the overall amino acid sequence of the aq065 protein differs considerably from that of E. coli YggH, the purified aq065 protein possessed a tRNA (m7G46) methyltransferase activity. The modified nucleoside and its location were determined by liquid chromatography-mass spectroscopy. To clarify the RNA recognition mechanism of the enzyme, we investigated the methyl transfer activity to 28 variants of yeast tRNAPhe and E. coli tRNAThr. It was confirmed that 5'-leader and 3'-trailer RNAs of tRNA precursor are not required for the methyl transfer. We found that the enzyme specificity was critically dependent on the size of the variable loop. Experiments using truncated variants showed that the variable loop sequence inserted between two stems is recognized as a substrate, and the most important recognition site is contained within the T stem. These results indicate that the L-shaped tRNA structure is not required for methyl acceptance activity. It was also found that nucleotide substitutions around G46 in three-dimensional core decrease the activity.

An essential role for aspartate 264 in catalysis by tRNA-guanine transglycosylase from Escherichia coli

tRNA-guanine transglycosylase (TGT) catalyzes a post-transcriptional base-exchange reaction involved in the incorporation of the modified base queuine (Q) into the wobble position of certain tRNAs. Catalysis by TGT occurs through a double-displacement mechanism that involves the formation of a covalent enzyme-RNA intermediate (Kittendorf, J. D., Barcomb, L. M., Nonekowski, S. T., and Garcia, G. A. (2001) Biochemistry 40, 14123-14133). The TGT chemical mechanism requires the protonation of the displaced guanine and the deprotonation of the incoming heterocyclic base. Based on its position in the active site, it is likely that aspartate 264 is involved in these proton transfer events. To investigate this possibility, site-directed mutagenesis was employed to convert aspartate 264 to alanine, asparagine, glutamate, glutamine, lysine, and histidine. Biochemical characterization of these TGT mutants revealed that only the conservative glutamate mutant retained catalytic activity, with Km values for both tRNA and guanine 3-fold greater than those for wild-type, whereas the kcat was depressed by an order of magnitude. Furthermore, of these six TGT mutants, only the TGT(D264E) was capable of forming a TGT.RNA covalent intermediate; however, unlike wild-type TGT, only hydroxylamine is capable of cleaving the TGT(D264E).RNA covalent complex. In an effort to better understand the unique biochemical properties of the D264E TGT mutant, we solved the crystal structure of the Zymomonas mobilis TGT with the analogous mutation (D280E). The results of these studies support two roles for aspartate 264 in catalysis by TGT, protonation of the leaving guanine and deprotonation of the incoming preQ1.

Chemical trapping and crystal structure of a catalytic tRNA guanine transglycosylase covalent intermediate

Prokaryotic tRNA guanine transglycosylase (TGT) catalyzes replacement of guanine (G) by 7-aminomethyl-7-deazaguanine (PreQ1) at the wobble position of four specific tRNAs. Addition of 9-deazaguanine (9dzG) to a reaction mixture of Zymomonas mobilis TGT and an RNA substrate allowed us to trap, purify and crystallize a chemically competent covalent intermediate of the TGT-catalyzed reaction. The crystal structure of the TGT-RNA-9dzG ternary complex at a resolution of 2.9 A reveals, unexpectedly, that RNA is tethered to TGT through the side chain of Asp280. Thus, Asp280, instead of the previously proposed Asp102, acts as the nucleophile for the reaction. The RNA substrate adopts an unusual conformation, with four out of seven nucleotides in the loop region flipped out. Interactions between TGT and RNA revealed by the structure provide the molecular basis of the RNA substrate requirements by TGT. Furthermore, reaction of PreQ1 with the crystallized covalent intermediate provides insight into the necessary structural changes required for the TGT-catalyzed reaction to occur.

tRNA-guanine transglycosylase from E. coli: a ping-pong kinetic mechanism is consistent with nucleophilic catalysis

tRNA-guanine transglycosylase (TGT) is a key enzyme in the post-transcriptional modification of certain tRNAs with the pyrrolopyrimidine base queuine. TGT is required for pathogenicity in Shigella flexneri, a human pathogen, and therefore is potentially a novel antibacterial target. Previous work has indicated that the TGT reaction proceeds through a covalent enzyme-tRNA complex [Biochemistry 40 (2001) 14123]. To further substantiate this mechanism, the determination of the kinetic mechanism for the TGT reaction was undertaken. Computational and graphical analyses of initial velocity data are most consistent with a ping-pong kinetic mechanism. The modes of inhibition of 7-methylguanine with respect to both guanine (competitive) and tRNA (uncompetitive) indicate that tRNA binds first to the enzyme. This kinetic mechanism is consistent with the covalent intermediate chemical mechanism and with our earlier study of a mechanism-based inhibitor [7-fluoromethyl-7-deazaguanine, Biochemistry 34 (1995) 15539] in which TGT inactivation was dependent upon the presence of tRNA.

Aquifex aeolicus tRNA (Gm18) methyltransferase has unique substrate specificity. TRNA recognition mechanism of the enzyme

Transfer RNA (guanosine-2')-methyltransferase (Gm-methylase) catalyzes the transfer of a methyl group from S-adenosyl-l-methionine to 2'-OH of G18 in the D-loop of tRNA. Based on their mode of tRNA recognition, Gm-methylases can be divided into the following two types: type I having broad specificity toward the substrate tRNA, and type II that methylates only limited tRNA species. Protein synthesized by in vitro cell-free translation revealed that Gm-methylase encoded in the Aquifex aeolicus genome is a novel type II enzyme. Experiments with chimeric tRNAs and mini- and micro-helix RNAs showed that the recognition region of this enzyme is included within the D-arm structure of tRNALeu and that a bulge is essentially required. Variants of tRNALeu, tRNASer, and tRNAPhe revealed that a combination of certain base pairs in the D-stem is strongly recognized by the enzyme, that 4 bp in the D-stem enhance methyl acceptance activity, and that the Py16Py17G18G19 sequence is important for efficient methyl transfer. The methyl acceptance activities of all the A. aeolicus tRNA genes, which can be classified into 14 categories on the basis of their D-arm structure, were tested. The results clearly showed that the substrate recognition mechanism elucidated by the variant experiments was applicable to their native substrates.

Biosynthesis of the 7-deazaguanosine hypermodified nucleosides of transfer RNA

Transfer RNA (tRNA) is structurally unique among nucleic acids in harboring an astonishing diversity of post-transcriptionally modified nucleoside. Two of the most radically modified nucleosides known to occur in tRNA are queuosine and archaeosine, both of which are characterized by a 7-deazaguanosine core structure. In spite of the phylogenetic segregation observed for these nucleosides (queuosine is present in Eukarya and Bacteria, while archaeosine is present only in Archaea), their structural similarity suggested a common biosynthetic origin, and recent biochemical and genetic studies have provided compelling evidence that a significant portion of their biosynthesis may in fact be identical. This review covers current understanding of the physiology and biosynthesis of these remarkable nucleosides, with particular emphasis on the only two enzymes that have been discovered in the pathways: tRNA-guanine transglycosylase (TGT), which catalyzes the insertion of a modified base into the polynucleotide with the concomitant elimination of the genetically encoded guanine in the biosynthesis of both nucleosides, and S-adenosylmethionine:tRNA ribosyltransferase-isomerase (QueA), which catalyzes the penultimate step in the biosynthesis of queuosine, the construction of the carbocyclic side chain.

The Escherichia coli tRNA-guanine transglycosylase can recognize and modify DNA

tRNA-guanine transglycosylase (TGT) catalyzes the exchange of queuine (or a precursor) for guanine 34 in tRNA. The minimal RNA recognition motif for TGT has been found to involve a UGU sequence in the anticodon loop of the queuine-cognate tRNAs. Recent studies have shown that the enzyme is capable of recognizing the UGU sequence in alternative contexts (Kung, F. L., Nonekowski, S., and Garcia, G. A. (2000) RNA 6, 233-244) and have investigated the role of the first U of the UGU sequence in tRNA recognition by TGT (Nonekowski, S. T., and Garcia, G. A. (2001) RNA 7, 1432-1441). The TGT reaction involves the breakage and re-formation of a glycosidic bond. To rule out a potential chemical mechanism involving the 2'-hydroxyl at position 34, we synthesized and evaluated an RNA minihelix with 2'-deoxy-G at 34. The high level of activity exhibited by this analogue indicates that the 2'-hydroxyl of G(34) is not required for catalysis. Furthermore, we find that TGT can recognize analogues composed entirely of DNA, but only when 2'-deoxyuridines replace the thymidines in the DNA. The requirement for uridine bases for recognition is perhaps not surprising given the UGU recognition motif for TGT. However, it is not clear if the uracil requirement is due to specific recognition by TGT or due to the effect of uracils on the conformation of the oligonucleotide.

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.

Queuosine modification of tRNA: a case for convergent evolution

Queuosine is a hypermodified nucleoside found in position 34, the anticodon wobble position, of four tRNA species. This modification is distributed with near uniformity across all life forms found on this planet. Yet the molecular mechanisms involved with accomplishing this ubiquitous posttranscriptional modification of tRNA are dramatically different between prokaryotic and eukaryotic organisms, which suggests that these were formed by convergent evolution of a fundamental life process essential to nearly all life forms. This minireview describes the differences between these modification systems and points to a new direction for developing research on the molecular function queuosine-modified tRNA in diverse species.