Queuosine Formation in Eukaryotic tRNA Occurs via a Mitochondria-localized Heteromeric Transglycosylase

tRNA guanine transglycosylase (TGT) enzymes are responsible for the formation of queuosine in the anticodon loop (position 34) of tRNA^Asp, tRNA^Asn, tRNA^His, and tRNA^Tyr; an almost universal event in eubacterial and eukaryotic species. Despite extensive characterization of the eubacterial TGT the eukaryotic activity has remained undefined. Our search of mouse EST and cDNA data bases identified a homologue of the Escherichia coli TGT and three spliced variants of the queuine tRNA guanine transglycosylase domain containing 1 (QTRTD1) gene. QTRTD1 variant_1 (Qv1) was found to be the predominant adult form. Functional cooperativity of TGT and Qv1 was suggested by their coordinate mRNA expression in Northern blots and from their association in vivo by immunoprecipitation. Neither TGT nor Qv1 alone could complement a tgt mutation in E. coli. However, transglycosylase activity could be obtained when the proteins were combined in vitro. Confocal and immunoblot analysis suggest that TGT weakly interacts with the outer mitochondrial membrane possibly through association with Qv1, which was found to be stably associated with the organelle.Queuosine (Q³; (7-{(4,5-cis-dihydroxy-2-cyclo-penten-1-yl)-amino]methyl}-7-deazaguanosine) is a modified 7-deazaguanosine molecule found at the wobble position of transfer RNA that contains a GUN anticodon sequence: tRNA^Tyr, tRNA^Asn, tRNA^His, and tRNA^Asp (1). The Q-modification is widely distributed in nature in the tRNA of eubacteria, plants, and animals; a notable exception being yeast and plant leaf cells (2, 3). Interestingly, Q-modification has also been detected in aspartyl tRNA from mitochondria of rat (4) and opossum (5). In most eukaryotes, the Q molecule can be further modified by the addition of a mannosyl group to Q-tRNA^Asp and a galactosyl group to Q-tRNA^Tyr (1).Eubacteria are unique in their ability to synthesize Q. As part of this biosynthetic process, the eubacterial tRNA guanine transglycosylase (TGT) enzyme inserts the Q precursor molecule, 7-aminomethyl-7-deazaguanine (preQ₁) into tRNA, which is then converted to Q by two further enzymatic steps at the tRNA level (6). Eukaryotes by contrast salvage queuosine from food and enteric bacteria either as the free base (referred to as queuine) or as queuosine 5′-phosphate subsequent to normal tRNA turnover (7). A Q-related molecule, archaeosine, is found at position 15 of the D loop of most archaeal tRNA, where it functions to stabilize the tRNA structure (8). The enzyme involved in archaeosine biosynthesis is structurally and mechanistically related to the eubacterial TGT but with adaptations necessitated by the differences imposed by its unique substrate and tRNA specificity (9, 10).The crystal structure of the Zymononas mobilis (Z. mobilis) TGT has been determined and revealed the enzyme to be an irregular (β/α)₈ TIM barrel with a C-terminal zinc-binding subdomain (11). Insight into the residues involved in catalysis came from mutational and kinetic analysis of the recombinant Escherichia coli enzyme (12) and from the Z. mobilis TGT structure as an RNA-bound intermediate complexed to the final preQ₁-modified RNA product (13). This work showed the essential role of Asp-280 (Z. mobilis numbering) as the active site nucleophile. Asp-102, which was originally ascribed the role of active site nucleophile, functions as a general acid/base during catalysis (12, 10). Although, the E. coli and Z. mobilis TGT enzymes are monomeric in solution (14), at high protein concentrations the E. coli enzyme can oligomerize (15), and structural data from the Z. mobilis TGT has shown the formation of a 2:1 complex with tRNA; a possible functional requirement for catalysis (10).In contrast to the eubacterial enzyme, which is a single protein species, purification of the eukaryotic TGT suggested that the catalytically active enzyme is a heterodimeric molecule: subunits of 60 and 43 kDa in rabbit erythrocytes (16), 66 and 32 kDa in bovine liver (17), 60 and 34.5 kDa in rat liver (18), and a homodimer of two 68-kDa proteins in wheat germ (16, 19). A partial amino acid sequence was recovered from two of these active enzyme preparations. The identity of the proteins from bovine liver (17) could not be assigned at the time of publication. However, our searches show that the peptides from the larger 65-kDa subunit are identical to asparaginyl tRNA synthetase, and those of the smaller 32-kDa subunit correspond to 2,4-dienoyl CoA reductase. A highly pure preparation from rabbit reticulocytes (20) gave peptides with homology to the immunophilin p59, human elongation factor 2 (EF2), and a deubiquitinating enzyme, USP14. It is noteworthy that none of the peptide sequences obtained showed similarity to the eubacterial TGT. The results do suggest, however, that in eukaryotes the TGT activity could be embedded in a multisubunit complex.Most recently, Deshpande and Katze (21) identified a cDNA clone encoding a putative TGT catalytic subunit. Cloning the cDNA into a mammalian expression plasmid reconstituted TGT activity in GC₃/c1 cells, which are known to be naturally deficient in Q-containing tRNA (22). In this study, we identify for the first time the composition of the eukaryotic tRNA guanine transglycosylase, reconstitute the catalytic activity in vitro, and examine the intracellular distribution of the active subunits.