Exploring GpG bases next to anticodon in tRNA subsets

Transfer RNA (tRNA) structure, modifications and functions are evolutionary and established in bacteria, archaea and eukaryotes. Typically the tRNA modifications are indispensable for its stability and are required for decoding the mRNA into amino acids for protein synthesis. A conserved methylation has been located on the anticodon loop specifically at the 37^th position and it is next to the anticodon bases. This modification is called as m1G37 and it is catalyzed by tRNA (m¹G37) methyltransferase (TrmD). It is deciphered that G37 positions occur on few additional amino acids specific tRNA subsets in bacteria. Furthermore, Archaea and Eukaryotes have more number of tRNA subsets which contains G37 position next to the anticodon and the G residue are located at different positions such as G36, G37, G38, 39, and G40. In eight bacterial species, G (guanosine) residues are presents at the 37^th and 38^th position except three tRNA subsets having G residues at 36^th and 39^th positions. Therefore we propose that m1G37 modification may be feasible at 36^th, 37^th, 38^th, 39^th and 40^th positions next to the anticodon of tRNAs. Collectively, methylation at G residues close to the anticodon may be possible at different positions and without restriction of anticodon 3^rd base A, C, U or G.     

Selenium metabolism in Drosophila. Characterization of the selenocysteine tRNA population.

The selenocysteine (Sec) tRNA population in Drosophila melanogaster is aminoacylated with serine, forms selenocysteyl-tRNA, and decodes UGA. The Km of Sec tRNA and serine tRNA for seryl-tRNA synthetase is 6.67 and 9.45 nM, respectively. Two major bands of Sec tRNA were resolved by gel electrophoresis. Both tRNAs were sequenced, and their primary structures were indistinguishable and colinear with that of the corresponding single copy gene. They are 90 nucleotides in length and contain three modified nucleosides, 5-methylcarboxymethyluridine, N6-isopentenyladenosine, and pseudouridine, at positions 34, 37, and 55, respectively. Neither form contains 1-methyladenosine at position 58 or 5-methylcarboxymethyl-2'-O-methyluridine, which are characteristically found in Sec tRNA of higher animals. We conclude that the primary structures of the two bands of Sec tRNA resolved by electrophoresis are indistinguishable by the techniques employed and that Sec tRNAs in Drosophila may exist in different conformational forms. The Sec tRNA gene maps to a single locus on chromosome 2 at position 47E or F. To our knowledge, Drosophila is the lowest eukaryote in which the Sec tRNA population has been characterized to date.     

The anticodon of the maize chloroplast gene for tRNA Leu UAA is split by a large intron.

The maize chloroplast gene encoding tRNA Leu UAA has been sequenced. It contains a 458 base pair intron between the first and second bases of the anticodon. The tRNA is 88 nucleotides long (the 3'-terminal CCA sequence included which, however, is not encoded by the gene) and differs in only four nucleotides (modified nucleotides are not considered) from the corresponding isoacceptor from bean chloroplasts. The unusual position of the intron in this maize chloroplast tRNA gene suggests a splicing model different from that generally accepted for eukaryotic split tRNA genes.     

Enzymatic methylations: III. Cadaverine-induced conformational changes of E.coli tRNAfMet as evidenced by the availability of a specific adenosine and a specific cytidine residue for methylation+

A partially purified tRNA methylase fraction from rat liver, containing m(2)G- m(1)A- and m(5)C-methylase, was used to study the influence of Mg(++) and of the biogenic polyamine cadaverine on the enzymatic methylation of E.coli tRNA(fMet)in vitro. In presence of 1 or 10 mM Mg(++), guanosine no. 27 was methylated to m(2)G. In 1 mM Mg(++) plus 30 mM cadaverine, guanosine in position 27 and adenosine in position 59 were methylated. In presence of 30 mM cadaverine alone tRNA(fMet) accepted three methyl groups: in addition to guanosine no. 27 and adenosine no. 59 cytidine no. 49 was methylated. In order to correlate tRNA(fMet) tertiary structure changes with the methylation patterns, differentiated melting curves of tRNA(fMet) were measured under the methylation conditions. It was shown that the thermodynamic stability of tRNA(fMet) tertiary structure is different in presence of Mg(++), or Mg(++) plus cadaverine, or cadaverine alone. From the differentiated melting curves and from the methylation experiments one can conclude that at 37 degrees in the presence of Mg(++) tRNA(fMet) has a compact structure with the extra loop and the TpsiC-loop protected by tertiary structure interactions. In Mg(++) plus cadaverine, the TpsiC-loop is available, while the extra loop is yet engaged in teritary structure (G-15: C-49) interactions. In cadaverine alone, the TpsiC-loop and the extra loop are free; hence under these conditions the open tRNA(fMet) clover leaf may be the substrate for methylation. In general, cadaverine destabilizes tRNA tertiary structure in the presence of Mg(++), and stabilizes tRNA(fMet) tertiary structure in the absence of Mg(++). This may be explained by a competition of cadaverine with Mg(++) for specific binding sites on the tRNA. On the basis of these experiments a possible role of biogenic polyamines in vivo may be discussed: as essential components of procaryotic and eucaryotic ribosomes they may together with ribosomal factors facilitate tRNA-ribosome binding during protein biosynthesis by opening the tRNA tertiary structure, thus making the tRNA's TpsiC-loop available for interaction with the complementary sequence of the ribosomal 5S RNA.     

Changes in transfer ribonucleic acids of Bacillus subtilis during different growth phases

The transfer ribonucleic acids (tRNAs) of B. subtilis at different growth phases are examined for changes in the composition and the methylation of minor constituents. The composition of the tRNAs indicates about equal amounts of adenosine and uridine, and of guanosine and cytidine. About 3-4 residues are present as modified bases in the average tRNA molecule. The net composition of tRNAs appears to remain unaltered during different growth phases. In vitro methylation of tRNAs indicates lack of methyl groups in both exponentially growing cells and spores. In vivo methylation studies show tRNA methylation occurs during the stationary phase in the absence of net tRNA synthesis. Thus, both in vitro and in vivo methylation indicates that the tRNAs in exponentially growing cells do not contain their full complement of modified bases. More complete modification is noted in tRNAs from stationary cells or spores. Hence, tRNA modifications in general are preserved with fidelity even in the dormant spore but the possibility is left open that specific modifications of selected isoacceptors of tRNAs may occur.     

Selective rescue of selenoprotein expression in mice lacking a highly specialized methyl group in selenocysteine tRNA

Selenocysteine (Sec) is the 21st amino acid in the genetic code. Its tRNA is variably methylated on the 2'-O-hydroxyl site of the ribosyl moiety at position 34 (Um34). Herein, we identified a role of Um34 in regulating the expression of some, but not all, selenoproteins. A strain of knock-out transgenic mice was generated, wherein the Sec tRNA gene was replaced with either wild type or mutant Sec tRNA transgenes. The mutant transgene yielded a tRNA that lacked two base modifications, N(6)-isopentenyladenosine at position 37 (i(6)A37) and Um34. Several selenoproteins, including glutathione peroxidases 1 and 3, SelR, and SelT, were not detected in mice rescued with the mutant transgene, whereas other selenoproteins, including thioredoxin reductases 1 and 3 and glutathione peroxidase 4, were expressed in normal or reduced levels. Northern blot analysis suggested that other selenoproteins (e.g. SelW) were also poorly expressed. This novel regulation of protein expression occurred at the level of translation and manifested a tissue-specific pattern. The available data suggest that the Um34 modification has greater influence than the i(6)A37 modification in regulating the expression of various mammalian selenoproteins and Um34 is required for synthesis of several members of this protein class. Many proteins that were poorly rescued appear to be involved in responses to stress, and their expression is also highly dependent on selenium in the diet. Furthermore, their mRNA levels are regulated by selenium and are subject to nonsense-mediated decay. Overall, this study described a novel mechanism of regulation of protein expression by tRNA modification that is in turn regulated by levels of the trace element, selenium.     

Genes coding for the selenocysteine-inserting tRNA species from Desulfomicrobium baculatum and Clostridium thermoaceticum: structural and evolutionary implications.

The genes (selC) coding for the selenocysteine-inserting tRNA species (tRNA(Sec)) from Clostridium thermoaceticum and Desulfomicrobium baculatum were cloned and sequenced. Although they differ in numerous positions from the sequence of the Escherichia coli selC gene, they were able to complement the selC lesion of an E. coli mutant and to promote selenoprotein formation in the heterologous host. The tRNA(Sec) species from both organisms possess all of the unique primary, secondary, and tertiary structural features exhibited by E. coli tRNA(Sec) (C. Baron, E. Westhof, A. Böck, and R. Giegé, J. Mol. Biol. 231:274-292, 1993). The structural and functional properties of the tRNA(Sec) species from prokaryotes analyzed thus far support the notion that tRNA(Sec) may be an evolutionarily conserved structure whose function in the primordial genetic code was to decode UGA with selenocysteine.     

Characterization of selenium-containing tRNAGlu from Clostridium sticklandii

A selenium-containing tRNA from Clostridium sticklandii has been shown to be an isoaccepting tRNAGlu (W.-M. Ching and T. C. Stadtman (1982) Proc. Natl. Acad. Sci. USA 79, 374-377). Not only is this tRNAGlu one of the most abundant selenium-containing tRNA species but it is also the major glutamate isoacceptor in this organism. The selenonucleoside, which is located at the first position of the anticodon, was identified as 5-methylaminomethyl-2-selenouridine (A. J. Wittwer, L. Tsai, W.-M. Ching, and T. C. Stadt (1984) Biochemistry 23, 4650-4655). Other modified nucleosides present in this tRNA include 4-thiouridine, pseudouridine, ribothymidine, modified guanosine, and two different modified adenosines. When this seleno-tRNAGlu is incubated in 1.0 M Tris X HCl, pH 8.5, partial deselenization occurs. Moreover, treatment with cyanogen bromide almost completely removes the selenium. The presence of selenium in this tRNAGlu is essential for its enzymatic acylation with glutamate. This seleno-tRNAGlu recognizes both GAA and GAG codons. However, at 10 mM magnesium, which is near the physiological range, the GAA codon is slightly favored. In a cell free translation system, the acylated seleno-tRNAGlu is a very active glutamate donor.     

Selective inhibition of selenocysteine tRNA maturation and selenoprotein synthesis in transgenic mice expressing isopentenyladenosine-deficient selenocysteine tRNA

Selenocysteine (Sec) tRNA (tRNA([Ser]Sec)) serves as both the site of Sec biosynthesis and the adapter molecule for donation of this amino acid to protein. The consequences on selenoprotein biosynthesis of overexpressing either the wild type or a mutant tRNA([Ser]Sec) lacking the modified base, isopentenyladenosine, in its anticodon loop were examined by introducing multiple copies of the corresponding tRNA([Ser]Sec) genes into the mouse genome. Overexpression of wild-type tRNA([Ser]Sec) did not affect selenoprotein synthesis. In contrast, the levels of numerous selenoproteins decreased in mice expressing isopentenyladenosine-deficient (i(6)A(-)) tRNA([Ser]Sec) in a protein- and tissue-specific manner. Cytosolic glutathione peroxidase and mitochondrial thioredoxin reductase 3 were the most and least affected selenoproteins, while selenoprotein expression was most and least affected in the liver and testes, respectively. The defect in selenoprotein expression occurred at translation, since selenoprotein mRNA levels were largely unaffected. Analysis of the tRNA([Ser]Sec) population showed that expression of i(6)A(-) tRNA([Ser]Sec) altered the distribution of the two major isoforms, whereby the maturation of tRNA([Ser]Sec) by methylation of the nucleoside in the wobble position was repressed. The data suggest that the levels of i(6)A(-) tRNA([Ser]Sec) and wild-type tRNA([Ser]Sec) are regulated independently and that the amount of wild-type tRNA([Ser]Sec) is determined, at least in part, by a feedback mechanism governed by the level of the tRNA([Ser]Sec) population. This study marks the first example of transgenic mice engineered to contain functional tRNA transgenes and suggests that i(6)A(-) tRNA([Ser]Sec) transgenic mice will be useful in assessing the biological roles of selenoproteins.     

A regulatory role for Sec tRNA[Ser]Sec in selenoprotein synthesis

Selenium is biologically active through the functions of selenoproteins that contain the amino acid selenocysteine. This amino acid is translated in response to in-frame UGA codons in mRNAs that include a SECIS element in its 3' untranslated region, and this process requires a unique tRNA, referred to as tRNA([Ser]Sec). The translation of UGA as selenocysteine, rather than its use as a termination signal, is a candidate restriction point for the regulation of selenoprotein synthesis by selenium. A specialized reporter construct was used that permits the evaluation of SECIS-directed UGA translation to examine mechanisms of the regulation of selenoprotein translation. Using SECIS elements from five different selenoprotein mRNAs, UGA translation was quantified in response to selenium supplementation and alterations in tRNA([Ser]Sec) levels and isoform distributions. Although each of the evaluated SECIS elements exhibited differences in their baseline activities, each was stimulated to a similar extent by increased selenium or tRNA([Ser]Sec) levels and was inhibited by diminished levels of the methylated isoform of tRNA([Ser]Sec) achieved using a dominant-negative acting mutant tRNA([Ser]Sec). tRNA([Ser]Sec) was found to be limiting for UGA translation under conditions of high selenoprotein mRNA in both a transient reporter assay and in cells with elevated GPx-1 mRNA. This and data indicating increased amounts of the methylated isoform of tRNA([Ser]Sec) during selenoprotein translation indicate that it is this isoform that is translationally active and that selenium-induced tRNA methylation is a mechanism of regulation of the synthesis of selenoproteins.     

Mutagenesis of selC, the gene for the selenocysteine-inserting tRNA-species in E. coli: effects on in vivo function.

The selenocysteine-inserting tRNA (tRNA(Sec)) of E. coli differs in a number of structural features from all other elongator tRNA species. To analyse the functional implications of the deviations from the consensus, these positions have been reverted to the canonical configuration. The following results were obtained: (i) inversion of the purine/pyrimidine pair at position 11/24 and change of the purine at position 8 into the universally conserved U had no functional consequence whereas replacements of U9 by G9 and of U14 by A14 decreased the efficiency of selenocysteine insertion as measured by translation of the fdhF message; (ii) deleting one basepair in the aminoacyl acceptor stem, thus creating the canonical 7 bp configuration, inactivated tRNA(Sec); (iii) replacement of the extra arm by that of a serine-inserting tRNA abolished the activity whereas reduction by 1 base or the insertion of three bases partially reduced function; (iv) change of the anticodon to that of a serine inserter abolished the capacity to decode UGA140 whereas the alteration to a cysteine codon permitted 30% read-through. However, the variant with the serine-specific anticodon efficiently inserted selenocysteine into a gene product when the UGA140 of the fdhF mRNA was replaced by a serine codon (UCA). Significantly, none of these changes resulted in the non-specific incorporation of selenocysteine into protein, indicating that the mRNA context also plays a major role in directing insertion. Taken together, the results demonstrate that the 8-basepair acceptor stem and the long extra arm are crucial determinants of tRNA(Sec) which enable decoding of UGA140 in the fdhF message.     

Function of Modified Nucleosides 7-Methylguanosine, Ribothymidine, and 2-Thiomethyl-N6-(Isopentenyl)adenosine in Procaryotic Transfer Ribonucleic Acid

To elucidate subtle functions of transfer ribonucleic acid (tRNA) modifications in protein synthesis, pairs of tRNA's that differ in modifications at specific positions were prepared from Bacillus subtilis. The tRNA's differ in modifications in the anticodon loop, the extra arm, and the TUC loop. The functional properties of these species were compared in aminoacylation, as well as in initiation and peptide bond formation, at programmed ribosomes. These experiments demonstrated the following. (i) In tRNA(f) (Met) the methylation of guanosine 46 in the extra arm to 7-methylguanosine by the 7-methylguanosine-forming enzyme from Escherichia coli changes the aminoacylation kinetics for the B. subtilis methionyl-tRNA synthetase. In repeated experiments the V(max) value is decreased by one-half. (ii) tRNA(f) (Met) species with ribothymidine at position 54 (rT54) or uridine at position 54 (U54) were obtained from untreated or trimethoprim-treated B. subtilis. The formylated fMet-tRNA(f) (Met) species with U54 and rT54, respectively, function equally well in an in vitro initiation system containing AUG, initiation factors, and 70s ribosomes. The unformylated Met-tRNA(t) (Met) species, however, differ from each other: "Met-tRNA(f) (Met) rT" is inactive, whereas the U54 counter-upart effectively forms the initiation complex. (iii) Two isoacceptors, tRNA(1) (Phe) and tRNA(2) (Phe), were obtained from B. subtilis. tRNA(1) (Phe) accumulates only under special growth conditions and is an incompletely modified precursor oftRNA(2) (Phe): in the first position of the anticodon, guanosine replaces Gm, and next to the 3' end of the anticodon (isopentenyl)adenosine replaces 2-thiomethyl-N(6)-(isopentenyl)adenosine. Both tRNA's behave identically in aminoacylation kinetics. In the factor-dependent AUGU(3)-directed formation of fMet-Phe, the undermodified tRNA(1) (Phe) is always less efficient at Mg(2+) concentrations between 5 and 15 mM than its mature counterpart.     

Formation of chromatographically unique species of transfer ribonucleic acid during amino acid starvation of relaxed-control Escherichia coli.

Examination of the transfer ribonucleic acid (tRNA) produced by starving, relaxed-control (rel minus) strains of Escherichia coli for required amino acids revealed the occurrence of a number of chromatographically unique subspecies. Leucine starvation results in the formation of new isoacceptor species of leucine-, histidine-, arginine-, valine-, and phenylalanine-specific tRNA and quantitative changes in the column profiles of serine, glycine, and isoleucine tRNA. Evidence that the unique tRNA species are synthesized de novo during amino acid starvation comes from the findings that the major unique leucine isoacceptor species is not formed in stringent control cells or in rel minus cells starved for uracil or treated with rifampin. Furthermore, heat treatment of the unique leucine tRNA does not alter its chromatographic behavior, indicating that the species is not an aggregate or nuclease-damaged form of a normal isoacceptor tRNA. The methyl acceptor activities of tRNA from leucine-starved and nonstarved rel+ or rel minus cells were found to be essentially the same. This result and the finding that the chromatographic behavior of the unique leucine-specific tRNA was not altered after treatment with tRNA methylase suggests that gross methyl deficiency is probably not the biochemical basis for the occurrence of the unique species.