tRNA Isoacceptors Research Articles

The influence of 5' codon context on translation termination in Saccharomyces cerevisiae.

Translation termination in vivo was studied in the yeast Saccharomyces cerevisiae using a translation-assay system. Codon changes that were made at position -2 relative to the stop codon, gave a 3.5-fold effect on termination in a release-factor-defective (sup45) mutant strain, in line with the effect observed in a wild-type strain. The influence of the -2 codon could be correlated to the charge of the corresponding amino acid residue in the nascent peptide; an acidic residue favoring efficient termination. Thus, the C-terminal end of the nascent peptide influences translation termination both in the bacterium Escherichia coli and to a lesser extent in the yeast S. cerevisiae. However, the sensitivity to the charge of the penultimate amino acid is reversed when the E. coli and S. cerevisiae are compared. Changing - 1 (P-site) codons in yeast gave a 10-fold difference in effect on the efficiency of termination. This effect could not be related to any property of the encoded last amino acid in the nascent peptide. Iso-codons read by the same tRNA (AAA/G, GAA/G) gave similar readthrough values. Codons for glutamine (CAA/G), glutamic acid (GAA/G) and isoleucine (AUA/C) that are read by different isoaccepting tRNAs are associated with an approximately twofold difference in each case in termination efficiency. This suggests that the P-site tRNA is able to influence termination at UGAC in yeast.

The hypotrichous ciliate Euplotes octocarinatus has only one type of tRNACys with GCA anticodon encoded on a single macronuclear DNA molecule.

Deviations from the universal genetic code have evolved independently several times in ciliated protozoa. Thus, in some species UAA and UAG are no longer used as termination codons, but are read as glutamine, whereas in the genus Euplotes , UGA is translated as cysteine. We have investigated the nature of the tRNACys isoacceptor responsible for decoding UGA in Euplotes cells. Southern hybridization analyses indicated that a single DNA molecule of 630 bp encoding tRNACys exists in the macronucleus of Euplotes octocarinatus . Cloning and sequencing of this fragment revealed that it contains only one copy of a tRNACys gene, which codes for a normal tRNACys with GCA anticodon. This is the first report of the characterization of a tRNA gene in any hypotrichous ciliate. It contains putative signals for initiation and termination of transcription by RNA polymerase III and can be transcribed efficiently in vitro in HeLa cell nuclear extract. Intensive studies on the DNA and tRNA level involving PCR analyses have not disclosed the existence of any tRNA Cys isoacceptor with UCA or ICA anticodons. Translation of the UGA codon by tRNA sub GCA sup Cys necessitates a G:A mispairing in the first anticodon position. We discuss a number of aspects which might contribute to the finding that a near-cognate tRNA isoacceptor efficiently translates the UGA stop codon.

Overproduction and purification ofEscherichia coli tRNALeu

Chemically synthesized genes encodingEscherichia coli tRNA (1) (Leu) and tRNA (2) (Leu) were ligated into the plasmid pTrc99B. then transformed intoEscherichia coli MT102, respectively. The positive transformants, named MT-Leu1 and MT-Leu2, were confirmed by DNA sequencing, and the conditions of cultivation for the two transformants were optimized. As a result, leucinc accepting activity of their total tRNA reached 810 and 560 pmol/A(260), respectively: the content of tRNA (1) (Leu) was 50% of total tRNA from MT-Leu1, while that of tRNA (2) (Leu) was 30% of total tRNA from MT-Leu2. Both tRNA(Leu)s from their rotal tRNs were fractionated to 1 600 pmol/A(260) after DEAE-Sepharose and BD-cellulose column chromatography. The accurate kinetic constants of aminoacylation of the two isoacceptors of tRNA(Leu) catalyzed by leucyl-tRNA synthetase were determined.

Coexistence of nuclear DNA-encoded tRNAVal(AAC) and mitochondrial DNA-encoded tRNAVal(UAC) in mitochondria of a liverwort Marchantia polymorpha.

The liverwort Marchantia polymorpha mitochondrial DNA encodes almost all tRNAs required for mitochondrial translation except for the isoleucine (AUU, AUC) and threonine (ACA, ACG) codons, while the missing tRNAs are supplied in part by the nucleus and imported in mitochondria. In this paper, we report a finding of two radically different nuclear tRNAVal(AAC) genes and import of the corresponding tRNA isoacceptors in M.polymorpha mitochondria. This finding is surprising since the mtDNA encodes the gene for tRNAVal(UAC), which alone was considered sufficient for translating all four valine codons GUN by the U/N wobble mechanism. The present results suggest for the first time that the import of ncDNA-encoded tRNAs may result in decoding overlaps in plant mitochondria. The coexistence of nuclear DNA-encoded tRNAVal(AAC) and mitochondrial DNA-encoded tRNAVal(UAC) in liverwort mitochondria and the significance for the decoding mechanism as well as evolution of tRNA import are discussed.

Wheat cytoplasmic arginine tRNA isoacceptor with a U*CG anticodon is an efficient UGA suppressor in vitro.

Many RNA viruses express part of their genomic information by read-through over internal termination codons. We have recently characterized tobacco cytoplasmic (cyt) and chloroplast (chl) tRNACmCATrp and tRNAGCACys as natural suppressor tRNAs that are able to read the leaky UGA codon in RNA-1 of tobacco rattle virus, albeit with different efficiencies. Here we have identified a third natural UGA suppressor in plants. We have purified and sequenced four cyt tRNAArg isoacceptors with ICG, CCG, U*CG and CCU anticodons from wheat germ. With the exception of tRNAICGArg, these are the first sequences of plant tRNAsArg. In order to study the potential suppressor activity of wheat tRNAsArg we have used in vitro synthesized mRNA transcripts in which different viral read-through regions had been placed. In vitro translation was carried out in a homologous wheat germ extract. We found that tRNAU*CGArg is an efficient UGA suppressor in vitro, whereas the other three tRNAArg isoacceptors exhibit no or very low suppressor activity. Interaction of tRNAU*CGArg with the UGA codon requires a G:U base pair at the third anticodon position. This is the first time that an arginine-accepting tRNA has been characterized as a natural UGA suppressor. A remarkable feature of cyt tRNAU*CGArg is its ability to misread the UGA at the end of the coat protein cistron in RNA-1 of pea enation mosaic virus, which is not accomplished by cyt tRNACmCATrp or cyt tRNAGCACys, due to an unfavourable codon context.

Nucleotide sequences and functional characterization of two tobacco UAG suppressor tRNA(Gln) isoacceptors and their genes.

We isolated and sequenced the two major tRNA(Gln) isoacceptors with CUG and UmUG anticodons from the cytoplasm of Nicotiana rustica. These are the first tRNAs(Gln) of nuclear origin characterized in plants. The tRNA(Gln) sequences were used to design probes for the isolation of the corresponding genes from a nuclear DNA library of N. rustica. The two cloned Nicotiana tRNA(Gln) genes, coding for either of the two isoacceptors, are efficiently transcribed in HeLa cell nuclear extract. In vitro translation in the presence of purified Nicotiana tRNAs(Gln) was carried out in a wheat germ extract partially depleted of endogenous tRNAs. Cytoplasmic (cyt) tRNA(Gln)CUG and to a lesser extent cyt tRNA(Gln)UmUG stimulated readthrough over the UAG stop codon present in the tobacco mosaic virus-specific context. The two tRNA(Gln) isoacceptors are the second class of natural UAG suppressors identified in plants, in addition to cyt tRNA(Tyr)GpsiA which has previously been characterized as the first natural UAG suppressor.

Replenishment of selenium deficient rats with selenium results in redistribution of the selenocysteine tRNA population in a tissue specific manner

We reported previously that the selenium status of rats influences both the steady-state levels and distributions of two selenocysteine tRNA isoacceptors and that these isoacceptors differ by a single methyl group attached to the ribosyl moiety at position 34. In this study, we demonstrate that repletion of selenium-deficient rats results in a gradual, tissue-dependent shift in the distribution of these isoacceptors. Rats fed a selenium-deficient diet possess a greater abundance of the species unmethylated on the ribosyl moiety at position 34 compared to the form methylated at this position. A redistribution of the Sec–tRNA isoacceptors occurred in tissues of selenium-supplemented rats whereby the unmethylated form gradually shifted toward the methylated form. This was true in each of four tissues examined, muscle, kidney, liver and heart, although the rate of redistribution was tissue-specific. Muscle manifested a predominance of two minor serine isoacceptors under conditions of extreme selenium-deficiency which also appeared to respond to selenium. Ribosomal binding studies revealed that one of the two additional isoacceptors decodes the serine codeword, AGU, and the second decodes the serine codeword, UCU. Interestingly, muscle and heart were the slower tissues to return to a `selenium adequate' tRNA distribution pattern.

Evolution of codon usage bias in Drosophila.

We first review what is known about patterns of codon usage bias in Drosophila and make the following points: (i) Drosophila genes are as biased or more biased than those in microorganisms. (ii) The level of bias of genes and even the particular pattern of codon bias can remain phylogenetically invariant for very long periods of evolution. (iii) However, some genes, even very tightly linked genes, can change very greatly in codon bias across species. (iv) Generally G and especially C are favored at synonymous sites in biased genes. (v) With the exception of aspartic acid, all amino acids contribute significantly and about equally to the codon usage bias of a gene. (vi) While most individual amino acids that can use G or C at synonymous sites display a preference for C, there are exceptions: valine and leucine, which prefer G. (vii) Finally, smaller genes tend to be more biased than longer genes. We then examine possible causes of these patterns and discount mutation bias on three bases: there is little evidence of regional mutation bias in Drosophila, mutation bias is likely toward A+T (the opposite of codon usage bias), and not all amino acids display the preference for the same nucleotide in the wobble position. Two lines of evidence support a selection hypothesis based on tRNA pools: highly biased genes tend to be highly and/or rapidly expressed, and the preferred codons in highly biased genes optimally bind the most abundant isoaccepting tRNAs. Finally, we examine the effect of bias on DNA evolution and confirm that genes with high codon usage bias have lower rates of synonymous substitution between species than do genes with low codon usage bias. Surprisingly, we find that genes with higher codon usage bias display higher levels of intraspecific synonymous polymorphism. This may be due to opposing effects of recombination.

Isolation of tRNA isoacceptors by affinity chromatography with immobilized elongation factor Tu from Escherichia coli

Elongation factor Tu (EF-Tu) from E. coli was coupled to activated CH Sepharose 4B. The immobilized EF-Tu maintained most of the guanosine nucleotide binding activity, but its ability to bind aminoacyl-tRNA depended on the type of complex used in the coupling reaction. The EF-Tu·GTP·aminoacyl-tRNA·kirromycin complex yielded an immobilized factor that was much more active in binding aminoacyl-tRNA than that obtained by coupling EF-Tu·GDP or EF-Tu·GDP·kirromycin to CH Sepharose 4B. Like the free factor, the immobilized EF-Tu·GTP did bind aminoacyl-tRNAs, but not unacylated tRNAs or N-acylated-aminoacyl-tRNAs. The antibiotic kirromycin was used to obtain the rapid conversion of EF-Tu·GDP to EF-Tu·GTP and the release of aminoacyl-tRNA from the matrix-bound EF-Tu by GDP. When total tRNA was aminoacylated by one amino acid only, a column of immobilized EF-Tu·GTP·kirromycin allowed the isolation of the aminoacylated tRNA from bulk tRNA. A rapid and nearly quantitative recovery of highly purified tRNA isoacceptors for various amino acids was obtained in one chromatographic step.

Accumulation of nuclear-encoded tRNA Thr (AGU) in mitochondria of the liverwort Marchantia polymorpha

The mitochondria) genome of the liverwort Marchantia polymorpha does not encode the full complement of tRNAs for the threonine and isoleucine codon boxes. To find the missing tRNA genes specifically for tRNA Thr in mitochondria, we have searched the genomic library and identified two clones (pTT1 and pTT2), encoding the identical tRNA Thr (AGU) gene copy with different 5′- and 3′-flanking sequences. By northern analysis, we demonstrate considerable accumulation of the nuclear encoded tRNA Thr and moderate expression of native tRN Thr(GGU) in mitochondria. Nonetheless, the imported and native tRNA Thr species together are not sufficient to translate all four threonine codons used in liverwort mitochondria, implicating mitochondria) import of at least one additional threonine isoacceptor tRNA.

Changes in aminoacylation levels of plastid tRNA species in dark-grown ragi ( Eleucine coracana) seedlings treated with phytohormones and light

Phytohormone- and light-induced changes in aminoacylation levels and isoacceptor distribution of plastid tRNAs in ragi coleoptiles were studied. Intact 7-day-old dark-grown ragi seedlings were given phytohormone, indoleacetic acid (IAA) or isopentenyladenine (i(6)A), and/or light treatments; coleoptiles were harvested 24 h following treatment, and plastid total tRNAs were isolated and compared with respect to amino acid acceptance levels and isoacceptor tRNA species distribution. We find that the overall amino acid acceptance of the plastid tRNA species is elevated following phytohormone and/or light treatments to dark-grown ragi seedlings. In particular, the relative acceptor activities for Leu and Tyr in i(6)A-treated dark-grown, Ile, Leu, Lys, Phe, Ser and Tyr in IAA-treated dork-grown, and Leu and Lys in i(6)A-treated light-grown ragi coleoptiles were 8 to 20 times higher. Significant changes in the distribution of Arg, Ile and Lys isoaccepting tRNA species were also observed after phytohormone and/or light treatments to dark-grown ragi seedlings. These data show that increases in the level of aminoacylation of plastid tRNAs and specific alterations of the plastid tRNA population do occur during phytohormone and light-induced plastid development in ragi coleoptiles. This is the first report of large increases in aminoacylation levels of plastid tRNAs triggered by exogenous phytohormone and/or light treatment(s) of dark-grown plants.

Mechanism, Specificity and General Properties of the Yeast Enzyme Catalysing the Formation of Inosine 34 in the Anticodon of Transfer RNA

In yeast, inosine is found at the first position of the anticodon (position 34) of seven different isoacceptor tRNA species, while in Escherichia coliit is present only in tRNA Arg. The corresponding tRNA genes all have adenosine at position 34. Using as substrates in vitroT7-runoff transcripts of 31 plasmids carrying each natural of synthetic tRNA gene harbouring an anticodon with adenosine 34, we have characterised a yeast enzyme that catalyses the conversion of adenosine 34 to inosine 34. The homologous E. colienzyme modifies adenosine 34 only in tRNAs with an arginine anticodon ACG. The base conversion occurs by a hydrolytic deamination- type reaction. This was determined by reversed phase high-pressure liquid chromatography/electrospray mass spectrometry analysis of the reaction product after in vitromodification in [ 180]water. This newly characterised tRNA : adenosine 34 deaminase was partially purified from yeast. It has a molecular mass of approximately 75 kDa, and it does not require any cofactor, except magnesium ions, to deaminate adenosine 34 efficiently in tRNA. The observed dependence of the enzymatic reaction on magnesium ions probably reflects the need for a correct tRNA architecture. Enzymatic recognition of tRNA does not depend on the presence of any ‘identity’ nucleoside other than adenosine 34. Likewise, the presence of pseudo-uridine 32 or 1-methyl-guanosine 37 in the anticodon loop does not interfere with inosine 34 biosynthesis. However, the efficacy of adenosine 34 to inosine 34 conversion depends on the nucleotide sequence of the anticodon loop and its proximal stem, the best tRNA substrates being those with a purine at position 35. Mutations that affect the size of the anticodon loop or one of several three-dimensional base-pairs abolish the capacity of the tRNA to be substrate for the yeast tRNA : adenosine 34 deaminase. Evidently, the activity of yeast tRNA : adenosine 34 deaminase depends more on the global structural feature (conformational stability/flexibility) of the L-shaped tRNA substrates than on the identity of any particular nucleotide other than adenosine 34. An apparent K mof 2.3 nM for its natural substrate tRNA Ser(anticodon AGA) was measured. Altogether, these results suggest that a single enzyme can account for the presence of inosine 34 in all seven cytoplasmic A34-containing precursor tRNAs in yeast.

Arginine aminoacylation identity is context-dependent and ensured by alternate recognition sets in the anticodon loop of accepting tRNA transcripts.

Yeast arginyl-tRNA synthetase recognizes the non-modified wild-type transcripts derived from both yeast tRNA(Arg) and tRNA(Asp) with equal efficiency. It discriminates its cognate natural substrate, tRNA(Arg), from non-cognate tRNA(Asp) by a negative discrimination mechanism whereby a single methyl group acts as an anti-determinant. Considering these facts, recognition elements responsible for specific arginylation in yeast have been searched by studying the in vitro arginylation properties of a series of transcripts derived from yeast tRNA(Asp), considered as an arginine isoacceptor tRNA. In parallel, experiments on similar tRNA(Arg) transcripts were performed. Unexpectedly, in the tRNA(Arg) context, arginylation is basically linked to the presence of residue C35, whereas in the tRNA(Asp) context, it is deeply related to that of C36 and G37 but is insensitive to the nucleotide at position 35. Each of these nucleotides present in one host, is absent in the other host tRNA. Thus, arginine identity is dependent on two different specific recognition sets according to the tRNA framework investigated.

HIV-1 Reverse Transcriptase Shows No Specificity for the Binding of Primer tRNALys3

The transcription initiation primer for HIV-1 is a specific cellular tRNA species, tRNALys3. We used several methods to assess the binding of tRNA by recombinant HIV-1 p51/p66 reverse transcriptase (RT), gel retardation analysis, intrinsic RT protein fluorescence quenching, and nitrocellulose filter binding assays. The binding of tRNA to RT was saturable, implying a distinct site or sites on the enzyme for tRNA interaction. However, this binding was non-selective, with all tRNA isoacceptors and total unfractionated tRNA binding with similar affinity as primer tRNALys3. In contrast, no significant binding of rRNA by RT was noted. Our results show that HIV-1 RT has no specificity for the binding of primer tRNALys3, and imply that factors other than RT sequences may be important for the selective incorporation of primer tRNA into the virion particle.

Co-variation of tRNA Abundance and Codon Usage in Escherichia coliat Different Growth Rates

We have used two-dimensional polyacrylamide gel electrophoresis to fractionate tRNAs from Escherichia coli. A sufficiently high degree of resolution was obtained for 44 out of 46 tRNA species in E. colito be resolved into individual electrophoretic components. These isolated components were identified by hybridization to tRNA-specific oligonucle otide probes. Systematic measurements of the abundance of each individual tRNA isoacceptor in E. coli, grown at rates varying from 0.4 to 2.5 doublings per hour, were made with the aid of this electrophoretic protocol. We find that there is a biased distribution of the tRNA abundance at all growth rates, and that this can be roughly correlated with the values of codon frequencies in the mRNA pools calculated for bacteria growing at different rates. The tRNA species cognate to abundant codons increase in concentration as the growth rate increases but not as dramatically as might be anticipated. The levels of most of the tRNA isoacceptors cognate to less abundant codons remain unchanged with increasing growth rates. The result of these changes in tRNA abundance is that the relative increase in the amounts of major tRNA species in the bacteria growing at the fastest growth rates is more modest than previous estimates from this laboratory suggested. Furthermore, a systematic error in previous estimates of ribosomal RNA content of the bacteria has been detected. This will account for the quantitative discrepancies between the previous and the present data for tRNA abundance.

The crystal structure of the ternary complex of T.thermophilus seryl-tRNA synthetase with tRNA(Ser) and a seryl-adenylate analogue reveals a conformational switch in the active site.

The low temperature crystal structure of the ternary complex of Thermus thermophilus seryl-tRNA synthetase with tRNA(Ser) (GGA) and a non-hydrolysable seryl-adenylate analogue has been refined at 2.7 angstrom resolution. The analogue is found in both active sites of the synthetase dimer but there is only one tRNA bound across the two subunits. The motif 2 loop of the active site into which the single tRNA enters interacts within the major groove of the acceptor stem. In particular, a novel ring-ring interaction between Phe262 on the extremity of this loop and the edges of bases U68 and C69 explains the conservation of pyrimidine bases at these positions in serine isoaccepting tRNAs. This active site takes on a significantly different ordered conformation from that observed in the other subunit, which lacks tRNA. Upon tRNA binding, a number of active site residues previously found interacting with the ATP or adenylate now switch to participate in tRNA recognition. These results shed further light on the structural dynamics of the overall aminoacylation reaction in class II synthetases by revealing a mechanism which may promote an ordered passage through the activation and transfer steps.

Codon Pair Utilization Biases Influence Translational Elongation Step Times

Two independent assays capable of measuring the relative in vivo translational step times across a selected codon pair in a growing polypeptide in the bacterium Escherichia coli have been employed to demonstrate that codon pairs observed in protein coding sequences more frequently than predicted (over-represented codon pairs) are translated slower than pairs observed less frequently than expected (under-represented codon pairs). These results are consistent with the findings that translational step times are influenced by codon context and that these context effects are related to the compatabilities of adjacent tRNA isoacceptor molecules on the surface of a translating ribosome. These results also support our previous suggestion that the frequency of one codon next to another has co-evolved with the structure and abundance of tRNA isoacceptors in order to control the rates of translational step times without imposing additional constraints on amino acid sequences or protein structures.

The Elongation Factor 3 Unique in Higher Fungi and Essential for Protein Biosynthesis Is an E Site Factor

Two elongation factors drive the ribosomal elongation cycle; elongation factor 1 alpha (EF-1 alpha) mediates the binding of an aminoacyl-tRNA to the ribosomal A site, whereas elongation factor 2 (EF-2) catalyzes the translocation reaction. Ribosomes from yeast and other higher fungi require a third elongation factor (EF-3) which is essential for the elongation process, but the step affected by EF-3 has not yet been identified. Here we demonstrate that the first and the third tRNA binding site (A and E sites, respectively) of yeast ribosomes are reciprocally linked; if the A site is occupied the E site has lost its binding capability, and vice versa, if the E site is occupied the A site has a low affinity for tRNAs. EF-3 is essential for EF-1 alpha-dependent A site binding of amino-acyl-tRNA only when the E site is occupied with a deacylated tRNA. The ATP-dependent activity of EF-3 is required for the release of deacylated tRNA from the E site during A site occupation.

Purification of Aminoacyl-tRNA by Affinity Chromatography on Immobilized Thermus thermophilus EF-Tu·GTP

Elongation factor Tu from Thermus thermophilus containing six histidine residues on its C-terminus, EF-Tu(CHis6), was used for purification of aminoacyl-tRNA isoacceptors, from aminoacylated bulk tRNA, by affinity chromatography. Preformed aminoacyl-tRNA·EF-Tu(CHis6)·GTP ternary complexes were immobilized on Ni2+-nitriloacetic acid agarose and the aminoacyl-tRNA was eluted at high ionic strength or with buffers containing GDP. Compared to alternative methods, the reported immobilization by C-terminal histidine residues does not lead to loss of EF-Tu′s affinity for aminoacyl-tRNA. The method is well suited for preparative isolation of aminoacylated tRNA isoacceptors and as an analytical tool to test tRNA composition and aminoacylation of tRNA in crude cellular extracts.

Highly Specific and Efficient Cleavage of Squid tRNALys Catalyzed by Magnesium Ions

Two lysine isoacceptor tRNAs corresponding to the codons AAA and AAG, respectively, were isolated from squid (Loligo bleekeri), and their nucleotide sequences were determined. During this analysis, we discovered that the tRNA with the anticodon CUU was efficiently cleaved at a specific site in the presence of magnesium ions, whereas the tRNA with the anticodon UUU was not. Cleavage occurred almost exclusively at the phosphodiester linkage between G15 and D16 (p16). The most remarkable feature of this cleavage reaction is that the end product was not a 2',3'-cyclic phosphate but was mainly a 3'-phosphate. Thus, this reaction was distinct from the well characterized cleavage of yeast tRNA(Phe) by lead and from reactions catalyzed by various other metalloribozymes. The presence of a cytidine residue at position 60 was required for efficient cleavage but was not crucial for the reaction, and the entire tRNA molecule had to be intact for this specific and efficient cleavage reaction. The present study provides evidence that there exists a new catalytic mechanism for cleavage of tRNA that exploits biologically ubiquitous ions rather than toxic, nonessential ions such as lead.