The molecular basis for the differential translation of TMV RNA in tobacco protoplasts and wheat germ extracts

Translation of tobacco mosaic virus (TMV) RNA in tobacco protoplasts yields the 17.5-K coat protein, a 126-K protein and a 183-K protein which is generated by an efficient readthrough over the UAG termination codon at the end of the 126-K cistron. In wheat germ extracts, however, only the 5'-proximal 126-K cistron is translated whereas the 183-K readthrough protein is not synthesized. Purification and sequence analysis of the endogenous tyrosine tRNAs revealed that the uninfected tobacco plant contains two tRNAs^Tyr, both with GΨA anticodons which stimulate the UAG readthrough in vitro and presumably in vivo. In contrast, ˜85% of the tRNA^Tyr from wheat germ contains a QΨA anticodon and ˜15% has a GΨA anticodon. Otherwise the sequences of tRNAs^Tyr from wheat germ and tobacco are identical. UAG readthrough and hence synthesis of the 183-K protein is only stimulated by tRNA^Tyr_GΨA and not at all by tRNA^Tyr_QΨA. The tRNAs^Tyr from wheat leaves were also sequenced. This revealed that adult wheat contains tRNA^Tyr_GΨA only. This is very much in contrast to the situation in animals, where Q-containing tRNAs are characteristic for adult tissues whereas Q deficiency is typical for the neoplastic and embryonic state.     

Queuine-containing isoacceptor of tyrosine tRNA in Drosophila melanogaster: Alteration of levels by divalent cations

Dietary cadmium causes the queuine-containing, Q(+), isoacceptors to increase relative to the guanine-containing, Q(?), ones of tRNA^Tyr, tRNA^His and tRNA^Asp of Drosophila melanogaster. Of the other divalent cations examined, Sr²⁺, Ni²⁺, Cu²⁺, Zn²⁺ and Hg²⁺, only Hg²⁺ failed to cause an increase in Q(+)tRNA^Tyr. For these results, all pre-adult stages of the organism were spent on media containing the divalent ions. Adult flies that had developed on a normal diet also responsed to divalent ions; Hg²⁺ as well as Cd²⁺, Sr²⁺ and Zn²⁺ caused an increase in Q(+)tRNA^Tyr in 4 days. Using adult flies, the rate of the response was measured; when placed on a Cd²⁺-containing diet, they formed significantly more Q(+)tRNA^Tyr within 24 h as compared to adults on a normal diet. Whether the queuine is derived from the diet or from de novo synthesis is yet to be determined. Since the metal ions represent a range of values in the ‘hard-soft’ classification, different sites of reaction are expected, yet for Drosophila a common result is an alteration in the ratio of Q(+) and Q(?) isoacceptors of these tRNAs. The transition to Q(+)tRNA may be an early indication of the metabolic imbalances resulting from the presence of the divalent cation.     

Yeast Asparagine (Asn) tRNA without Q Base Promotes Eukaryotic Frameshifting More Efficiently than Mammalian Asn tRNAs with or without Q Base

In this study, we compare the efficiency of Asn tRNA from mammalian sources with and without the highly modified queuosine (Q) base in the wobble position of its anticodon and Asn tRNA from yeast, which naturally lacks Q base, to promote frameshifting. Interestingly, no differences in the ability of the two mammalian Asn tRNAs to promote frameshifting were observed, while yeast tRNA^Asn_–Q promoted frameshifting more efficiently than its mammalian counterparts in both rabbit reticulocyte lysates and wheat germ extracts. The shiftability of yeast Asn tRNA is therefore not due, or at least not completely, to the lack of Q base and most likely the shiftiness resides in structural differences elsewhere in the molecule. However, we cannot absolutely rule out a role of Q base in frameshifting as wheat germ extracts and a lysate depleted of most of its tRNA and supplemented with calf liver tRNA contain both Asn tRNA with or without Q base.     

Dynamic modulation of Dnmt2-dependent tRNA methylation by the micronutrient queuine

Dnmt2 enzymes are cytosine-5 methyltransferases that methylate C38 of several tRNAs. We report here that the activities of two Dnmt2 homologs, Pmt1 from Schizosaccharomyces pombe and DnmA from Dictyostelium discoideum, are strongly stimulated by prior queuosine (Q) modification of the substrate tRNA. In vivo tRNA methylation levels were stimulated by growth of cells in queuine-containing medium; in vitro Pmt1 activity was enhanced on Q-containing RNA; and queuine-stimulated in vivo methylation was abrogated by the absence of the enzyme that inserts queuine into tRNA, eukaryotic tRNA-guanine transglycosylase. Global analysis of tRNA methylation in S. pombe showed a striking selectivity of Pmt1 for tRNA^Asp methylation, which distinguishes Pmt1 from other Dnmt2 homologs. The present analysis also revealed a novel Pmt1- and Q-independent tRNA methylation site in S. pombe, C34 of tRNA^Pro. Notably, queuine is a micronutrient that is scavenged by higher eukaryotes from the diet and gut microflora. This work therefore reveals an unanticipated route by which the environment can modulate tRNA modification in an organism.     

On the Possible Role of tRNA Base Modifications in the Evolution of Codon Usage: Queuosine and Drosophila

The best documented selection-based hypothesis to explain unequal usage of codons is based on the relative abundance of isoaccepting tRNAs. In unicellular organisms the most used codons are optimally translated by the most abundant tRNAs. The chemical bonding energies are affected by modification of the four traditional bases, in particular in the first anti-codon corresponding to the third codon position. One nearly universal modification is queuosine (Q) for guanine (G) in tRNA^His, tRNA^Asp, tRNA^Asn, and tRNA^Tyr; this changes the optimal binding from codons ending in C to no preference or a slight preference for U-ending codons. Among species of Drosophila, codon usage is constant with the exception of the Drosophila willistoni lineage which has shifted primary usage from C-ending codons to U/T ending codons only for these four amino acids. In Drosophila melanogaster Q containing tRNAs only predominate in old adults. We asked the question whether in D. willistoni these Q containing tRNAs might predominate earlier in development. As a surrogate for levels of modification we studied the expression of the gene (tgt) coding for the enzyme that catalyzes the substitution of Q for G in different life stages of D. melanogaster, D. pseudoobscura, and D. willistoni. Unlike the other two species, the highest tgt expression in D. willistoni is in young females producing eggs. Because tRNAs laid down in eggs persist through the early stages of development, this implies that Q modification occurs earlier in development in D. willistoni than in other Drosophila.     

Modification of guanine to queuine in transfer RNAs during development and aging

The degree of modification of guanine to queuine in the four queuine-containing tRNAs (Q-tRNAs) has been studied from rats of various age groups, and bacterial cells in different growth phases by measuring the amount of G-tRNA present in these tRNA preparations by tRNA-guanine transferase. In very young (one-week old) animals, only a small amount of G to Q modification was observed. However, this modification was essentially complete in the tRNAs of nine-month old animals, thereafter, the amount of Q decreased steadily. Studies of tRNAs from leukemic lymphocytes and bacterial cells indicated that the degree of G to Q modification was related to the metabolic state of the cell. The possible role of the Q-deficient isoacceptors in translation control is discussed.     

Queuine is incorporated into brain transfer RNA

Pig brain tRNA was assayed for the presence of queuosine in the first position of the anticodon for each of the Q-family of tRNAs (aspartyl, asparaginyl, histidyl and tyrosyl). The brain tRNA was aminoacylated with each of the four amino acids and the aminoacylated tRNA's analyzed by RPC-5 chromatography. The results of this study show that for all four tRNAs of the family, queuine is substituted for guanine in virtually 100% of the anticodons. Therefore, it can be concluded that queuine is able to cross the blood-brain barrier and that brain contains quanine-queuine tRNA transglycosylase, the enzyme responsible for the excision of guanine from the orginal transcipts of these tRNAs and insertion of queuine. The determination of whether the tRNA contained queuine was made from the elution profile of the RPC-5 chromatrograms and the results confirmed by a change in the RPC-5 elution profile when the tRNAs were reacted with BrCN or NaIO₄.     

Splicing of Arabidopsis tRNAMet precursors in tobacco cell and wheat germ extracts

Intron-containing tRNA genes are exceptional within nuclear plant genomes. It appears that merely two tRNA gene families coding for tRNA^Tyr _{G A} and elongator tRNA^Met _CmAU contain intervening sequences. We have previously investigated the features required by wheat germ splicing endonuclease for efficient and accurate intron excision from Arabidopsis pre-tRNA^Tyr. Here we have studied the expression of an Arabidopsis elongator tRNA^Met gene in two plant extracts of different origin. This gene was first transcribed either in HeLa or in tobacco cell nuclear extract and splicing of intron-containing tRNA^Met precursors was then examined in wheat germ S23 extract and in the tobacco system. The results show that conversion of pre-tRNA^Met to mature tRNA proceeds very efficiently in both plant extracts. In order to elucidate the potential role of specific nucleotides at the 3 and 5 splice sites and of a structured intron for pre-tRNA^Met splicing in either extract, we have performed a systematic survey by mutational analyses. The results show that cytidine residues at intron-exon boundaries impair pre-tRNA^Met splicing and that a highly structured intron is indispensable for pre-tRNA^Met splicing. tRNA precursors with an extended anticodon stem of three to four base pairs are readily accepted as substrates by wheat and tobacco splicing endonuclease, whereas pre-tRNA molecules that can form an extended anticodon stem of only two putative base pairs are not spliced at all. An amber suppressor, generated from the intron-containing elongator tRNA^Met gene, is efficiently processed and spliced in both plant extracts.     

Specific changes in lactate levels, lactate dehydrogenase patterns and cytochrome b559 in Dictyostelium discoideum caused by queuine

Higher eukaryotes contain tRNA transglycosylases that incorporate the guanine derivative queuine from the nutritional environment into specific tRNAs by exchange with guanine at position 34. Alterations in the queuosine content of specific tRNAs are suggested to be involved in regulatory mechanisms of major routes of metabolism during differentiation. Dictyostelium discoideum has been applied as a model to investigate the function of queuine or queuine-containing tRNAs. Axenic strains are supplied with queuine by peptone, but they grow equally well in a defined queuine-free medium. Queuine-lacking amoebae, starved in suspension culture for 24 h, lose their ability to differentiate into stalk cells and spores, whereas amoebae sufficiently supplied with queuine will overcome this metabolic stress and undergo further development when plated on agar. The results presented here show that D(-)-lactate occurs in the slime mould in millimolar amounts and that its level is remarkably decreased in queuine-lacking cells after 24 h of starvation in suspension culture. On isoelectric-focusing polyacrylamide gels, nine different forms of NAD-dependent D(-)-lactate dehydrogenase can be separated from extracts of vegetative cells, and six forms from extracts of the starved cells. Under queuine limitation, one form is missing in the starved cells. Low amounts of L(+)-lactate are usually found in vegetative amoebae but significantly less in queuine-lacking cells. Five forms of NAD-dependent L(+)-lactate dehydrogenase are detectable in extracts from vegetative, queuine-treated cells, and slight alterations occur in queuine-deficient amoebae. In the starved cells only one form of L(+)-lactate dehydrogenase is found, irrespective of the supply of queuine to the cells. A cytochrome of type b with an absorption maximum at 559 nm accumulates during starvation only in queuine-lacking cells; it might be a component of an NAD-independent lactic acid oxidoreductase as is cytochrome b 557 in yeast and be responsible for the reduced level of lactate in cells lacking queuine in tRNA.     

UAG readthrough during TMV RNA translation: isolation and sequence of two tRNAs with suppressor activity from tobacco plants

The hypothetical replicase or replicase subunit cistron in the 5'-proximal part of tobacco mosaic virus (TMV) RNA yields a major 126-K protein and a minor 183-K `readthrough' protein in vivo and in vitro. Two natural suppressor tRNAs were purified from uninfected tobacco plants on the basis of their ability to promote readthrough over the corresponding UAG termination codon in vitro. In a reticulocyte lysate the yield of 183-K readthrough protein increases from ˜10% in the absence of added tobacco plant tRNA up to ˜35% in the case of pure tRNA^Tyr added. Their amino acid acceptance and anticodon sequence (GψA) identifies the two natural suppressor tRNAs as the two normal major cytoplasmic tyrosine-specific tRNAs. tRNA^Tyr₁ has an A:U pair at the base of the TψC stem and an unmodified G₁₀, whereas tRNA^Tyr₂ contains a G:C pair in the corresponding location and m²G in position 10. This is the first case that, in a higher eukaryote, the complete structure is known of both the natural suppressor tRNAs and the corresponding viral RNA on which they exert their function. The corresponding codon-anticodon interaction, which is not in accordance with the wobble hypothesis, and the possible biological significance of the readthrough phenomenon is discussed.     

Modulation of Lactate Dehydrogenase Isozymes by Modified Base Queuine

The modified base queuine is a nutrient factor for lower and higher eukaryotes except yeast. It is synthesized in eubacteria and inserted into the wobble position of specific tRNAs (tRNA_GUN) in exchange of guanine at position 34. The tRNAs of Q family are completely modified in terminally differentiated somatic cells. However, mainly free queuine is present in embryonic and fast proliferating cells, tRNA remains Q deficient. Lactate dehydrogenase (LDH) A mRNA and LDH A protein is known to increase when cells are grown in hypoxic conditions. In the present study, the level of LDH isozymes is analyzed in different tissues of normal and cancerous (DLA) mice and the effect of queuine treatment on LDH isozyme is observed. LDH A isozyme is shown to increase in serum and liver of DLA mice. The level and activity of LDH A decreases on queuine treatment. In skeletal muscle and heart, LDH A isozyme decreases while LDH B increases in DLA mice. Queuine administration leads to change back towards normal. In case of brain, LDH A increases but LDH B decreases in DLA mice. Queuine treatment leads to decrease in A4 anaerobic isozymes of LDH. The results suggest that queuine suppresses anaerobic glycolytic pathway, which leads to tumor suppression of DLA mice.     

Crystal structure of glutamyl-queuosine tRNAAsp synthetase complexed with L-glutamate: structural elements mediating tRNA-independent activation of glutamate and glutamylation of tRNAAsp anticodon

Glutamyl-queuosine tRNA^Asp synthetase (Glu-Q-RS) from Escherichia coli is a paralog of the catalytic core of glutamyl-tRNA synthetase (GluRS) that catalyzes glutamylation of queuosine in the wobble position of tRNA^Asp. Despite important structural similarities, Glu-Q-RS and GluRS diverge strongly by their functional properties. The only feature common to both enzymes consists in the activation of Glu to form Glu-AMP, the intermediate of transfer RNA (tRNA) aminoacylation. However, both enzymes differ by the mechanism of selection of the cognate amino acid and by the mechanism of its activation. Whereas GluRS selects l-Glu and activates it only in the presence of the cognate tRNA^Glu, Glu-Q-RS forms Glu-AMP in the absence of tRNA. Moreover, while GluRS transfers the activated Glu to the 3′ accepting end of the cognate tRNA^Glu, Glu-Q-RS transfers the activated Glu to Q34 located in the anticodon loop of the noncognate tRNA^Asp. In order to gain insight into the structural elements leading to distinct mechanisms of amino acid activation, we solved the three-dimensional structure of Glu-Q-RS complexed to Glu and compared it to the structure of the GluRS·Glu complex. Comparison of the catalytic site of Glu-Q-RS with that of GluRS, combined with binding experiments of amino acids, shows that a restricted number of residues determine distinct catalytic properties of amino acid recognition and activation by the two enzymes. Furthermore, to explore the structural basis of the distinct aminoacylation properties of the two enzymes and to understand why Glu-Q-RS glutamylates only tRNA^Asp among the tRNAs possessing queuosine in position 34, we performed a tRNA mutational analysis to search for the elements of tRNA^Asp that determine recognition by Glu-Q-RS. The analyses made on tRNA^Asp and tRNA^Asn show that the presence of a C in position 38 is crucial for glutamylation of Q34. The results are discussed in the context of the evolution and adaptation of the tRNA glutamylation system.     

Chloroplastic methionyl-tRNA synthetase from wheat

Wheat chloroplastic methionyl-tRNA synthetase was isolated and appeared to be a monomer with a molecular weight of 75,000 daltons. Its catalytical properties in the aminoacylation for various isoacceptors tRNA_s^Met from E. coli and wheat germ revealed a recognition of prokaryotic tRNAs and wheat cytoplasmic tRNA_i^Met, but not tRNA_m^Met. Using pI determinations and catalytical properties, it could be detected in non-chloroplastic quiescent wheat germ a form of methionyl-tRNA synthetase having the same properties as the chloroplastic one's.     

Novel salvage of queuine from queuosine and absence of queuine synthesis in Chlorella pyrenoidosa and Chlamydomonas reinhardtii.

Partially purified extracts from Chlorella pyrenoidosa and Chlamydomonas reinhardtii catalyze the cleavage of queuosine (Q), a modified 7-deazaguanine nucleoside found exclusively in the first position of the anticodon of certain tRNAs, to queuine, the base of Q. This is the first report of an enzyme that specifically cleaves a 7-deazapurine riboside. Guanosine is not a substrate for this activity, nor is the epoxide a derivative of Q. We also establish that both algae can incorporate exogenously supplied queuine into their tRNA but lack Q-containing tRNA when cultivated in the absence of queuine, indicating that they are unable to synthesize Q de novo. Although no physiological function for Q has been identified in these algae, Q cleavage to queuine would enable algae to generate queuine from exogenous Q in the wild and also to salvage (and recycle) queuine from intracellular tRNA degraded during the normal turnover process. In mammalian cells, queuine salvage occurs by the specific cleavage of queuine from Q-5'-phosphate. The present data also support the hypothesis that plants, like animals, cannot synthesize Q de novo.     

Distribution of Cytokinin-active Ribonucleosides in Wheat Germ tRNA Species

The distribution of cytokinin activity in wheat (Triticum aestivum) germ tRNA fractionated by BD-cellulose and RPC-5 chromatography has been examined. As in other organisms, the cytokinin moieties in wheat germ tRNA appear to be restricted to tRNA species that would be expected to respond to codons beginning with U. Only a few of the wheat germ tRNA species in this coding group actually contain cytokinin modifications. Cytokinin activity was associated with isoaccepting tRNA^Ser species and with a minor tRNA^Leu species from wheat germ. All other wheat germ tRNA species corresponding to codons beginning with U were devoid of cytokinin activity in the tobacco callus bioassay.     

Genes for tRNAAsp,tRNAPro, tRNATyr and two tRNAsSer in wheat mitochondrial DNA

We have begun a systematic search for potential tRNA genes in wheat mtDNA, and present here the sequences of regions of the wheat mitochondrial genome that encode genes for tRNA^Asp (anticodon GUC), tRNA^Pro (UGG), tRNA^Tyr (GUA), and two tRNAs^Ser (UGA and GCU). These genes are all solitary, not immediately adjacent to other tRNA or known protein coding genes. Each of the encoded tRNAs can assume a secondary structure that conforms to the standard cloverleaf model, and that displays none of the structural aberrations peculiar to some of the corresponding mitochondrial tRNAs from other eukaryotes. The wheat mitochondrial tRNA sequences are, on average, substantially more similar to their eubacterial and chloroplast counterparts than to their homologues in fungal and animal mitochondria. However, an analysis of regions 150 nucleotides upstream and 100 nucleotides downstream of the tRNA coding regions has revealed no obvious conserved sequences that resemble the promoter and terminator motifs that regulate the expression of eubacterial and some chloroplast tRNA genes. When restriction digests of wheat mtDNA are probed with ³²P-labelled wheat mitochondrial tRNAs, <20 hybridizing bands are detected, whether enzymes with 4 bp or 6 bp recognition sites are used. This suggests that the wheat mitochondrial genome, despite its large size, may carry a relatively small number of tRNA genes.     

Presence of queuine in Drosophila melanogaster: correlation of free pool with queuosine content of tRNA and effect of mutations in pteridine metabolism.

Queuine, a modified form of 7-deazaguanine present in certain transfer RNAs, is shown to occur in Drosophila melanogaster adults in a free form and its concentration varies as a function of age, nutrition and genotype. In several, but not all mutant strains, the concentrations of queuine and the Q(+) (queuine-containing) form of tRNATyr are correlated. The bioassay employs L-M cells which respond to the presence of queuine by an increase in their Q(+)tRNAAsp that is accompanied by a decrease in the Q(-)tRNAAsp isoacceptors. The increase in Q(+)tRNATyr in Drosophila that occurs on a yeast diet is accompanied by an increase in queuine. Similarly the increase of Q(+)tRNAs with age also is accompanied by an increase in free queuine. In two mutants, brown and sepia, these correlations were either diminished or failed to occur. Indeed, the extract of both mutants inhibited the response of the L-M cells to authentic queuine. When the pteridines that occur at abnormally high levels in sepia were used at 1 x 10(-6)M, the inhibition of the L-M cell assay occurred in the order biopterin greater than pterin greater than sepiapterin. These pteridines were also inhibitory for the purified guanine:tRNA transglycosylase from rabbit but the relative effectiveness then was pterin greater than biopterin greater than sepiapterin. Pterin was competitive with guanine in the enzyme reaction with Ki = 0.9 x 10(-7)M. Also when an extract of sepia was chromatographed on Sephadex G-50, the pteridine-containing fractions only were inhibitory toward the L-M cell assay or the enzyme assay. These results indicate that free queuine occurs in Drosophila but also that certain pteridines may interfere with the incorporation of queuine into RNA.