tRNA-guanine transglycosylase from Escherichia coli: molecular mechanism and role of aspartate 89.

The enzyme tRNA-guanine transglycosylase (TGT, EC 2.4.2.29) catalyzes a posttranscriptional transglycosylation reaction involved in the incorporation of the modified base queuine [Q, 7-(4,5-cis-dihydroxy-2-cyclopenten-1-ylaminomethyl)-7-deazaguanine] into tRNA. Previously, the crystal structure of the TGT from Zymomonas mobilis was solved in complex with preQ(1) (the substrate for the eubacterial TGT) [Romier et al. (1996) EMBO J. 15, 2850-2857]. An aspartate residue at position 102 (position 89 in the Escherichia coli TGT) was proposed to play a nucleophilic role in an associative catalytic mechanism. Although this is an attractive and precedented mechanism, a dissociative mechanism is equally plausible. In a dissociative mechanism, aspartate 89 would provide electrostatic stabilization of an oxocarbenium ion intermediate that is formed by dissociation of guanine. To clarify the nature of the catalytic mechanism of TGT, we have generated and characterized four mutations of aspartate 89 in the E. coli TGT (alanine, asparagine, cysteine, and glutamate). All four mutant TGTs were able to noncovalently bind tRNA, but only the glutamate mutant was able to form a stable complex with the RNA substrate under denaturing conditions that was comparable to wild type. Furthermore, the glutamate mutant was the only mutant TGT that demonstrated significant activity. Kinetic parameters were determined for this enzyme and shown to be comparable to wild type, revealing that the enzyme is considerably tolerant of the positioning of the carboxylate. Under conditions of high enzyme concentrations and long time courses, the alanine, asparagine, and cysteine mutants showed very low levels (ca. 10(3)-fold lower than wild type) of activity that were linear with respect to enzyme concentration and dependent upon pH in a fashion similar to that of the wild type. However, the observed initial velocities were too low to accurately determine k(cat) and K(m) values. We hypothesize that the activity observed for these mutants is most likely derived from host strain TGT (wt) contamination. These results are most consistent with aspartate 89 acting as a nucleophile in an associative catalytic mechanism.

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.

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).

tRNA-guanine transglycosylase (TGT) is a key enzyme involved in the posttranscriptional modification of tRNA across the three kingdoms of life. In eukaryotes and eubacteria, TGT is involved in the introduction of queuine into the anticodon of the cognate tRNAs. In archaebacteria, TGT is responsible for the introduction of archaeosine into the D-loop of the appropriate tRNAs. The tRNA recognition patterns for the eubacterial (Escherichia coli) TGT have been studied. These studies are all consistent with a restricted recognition motif involving a U-G-U sequence in a seven-base loop at the end of a helix. While attempting to investigate the potential of negative recognition elements in noncognate tRNAs via the use of chimeric tRNAs, we have discovered a second recognition site for the E. coli TGT in the TpsiC arm of in vitro-transcribed yeast tRNA(Phe). Kinetic analyses of synthetic mutant oligoribonucleotides corresponding to the TpsiC arm of the yeast tRNA(Phe) indicate that the specific site of TGT action is G53 (within a U-G-U sequence at the transition of the TpsiC stem into the loop). Posttranscriptional base modifications in tRNA(Phe) block recognition by TGT, most likely due to a stabilization of the tRNA structure such that G53 is inaccessible to TGT. These results demonstrate that TGT can recognize the U-G-U sequence within a structural context that is different than the canonical U-G-U in the anticodon loop of tRNA(Asp). Although it is unclear if this second recognition site is physiologically relevant, this does suggest that other RNA species could serve as substrates for TGT in vivo.