Primary structure of baker''s yeast tRNAVal 2b.

The minor form of valine tRNA from baker's yeast-tRNAVal 2b--purified by column chromatography was completely digested with guanylo-RNase and pancreatic RNase. The products of these digestions were separated by a combination of thin-layer chromatography on cellulose and high voltage electrophoresis on DEAE-paper and then identified. The halves of tRNA Val 2b were prepared by partial digestion with pancreatic RNase, and their complete guanylo-RNase and pancreatic RNase digests were analysed. Basing on the obtained data the primary structure of baker's yeast tRNA Val 2b was reconstructed.     

Purification and characterization of Chlamydomonas reinhardtii chloroplast glutamyl-tRNA synthetase, a natural misacylating enzyme

Glutamyl-tRNA synthetase from Chlamydomonas reinhardtii was purified by sequential column chromatography on DEAE-cellulose, phosphocellulose, Mono Q, and Mono S. The apparent molecular mass of the protein when analyzed under both denaturing conditions (sodium dodecyl sulfate-polyacrylamide gel electrophoresis) and nondenaturing conditions (rate zonal sedimentation on glycerol gradients) was 62,000 Da; this indicates that the active enzyme is a monomer. The purified glutamyl-tRNA synthetase was identified as the chloroplast enzyme by its tRNA charging specificity. Reversed-phase chromatography of unfractionated C. reinhardtii tRNA resolved four peaks of glutamate acceptor RNA when assayed with the purified enzyme. The enzyme can also glutamylate Escherichia coli tRNA(2Glu), but not cytoplasmic tRNA(Glu) from yeast or barley. In addition, the enzyme misacylates chloroplast tRNA(Gln) with glutamate. A similar mischarging phenomenon has been demonstrated for the barley chloroplast enzyme (Sch?n, A., Kannangara, C.G., Gough, S., and S?ll, D. (1988) Nature 331, 187-190) and for Bacillus subtilis glutamyl-tRNA synthetase (Proulx, M., Duplain, L., Lacoste, L., Yaguchi, M., and Lapointe, J. (1983) J. Biol. Chem. 258, 753-759).     

Methylation of an adenosine in the D-loop of specific transfer RNAs from yeast by a procaryotic tRNA (adenine-1) methyltransferase.

tRNA (adenine-1) methyltransferase occurs in Bacillus subtilis. Eucaryotic tRNAThr and tRNATyr from yeast in which 1-methyladenosine (m1A) is already present in the TpsiC loop, can be methylated in vitro with S-adenosylmethionine and B. subtilis extracts. Each of the specific tRNAs accepts 1 mol of methyl groups per mol tRNA. The enzyme transforms into m1A the 3'-terminal adenylic acid residue of the dihydrouridine loop, a new position for a modified adenosine residue in tRNA. Both tRNAs have the sequence Py-A-A-G-G-C-m2(2)G in the D-loop and D-stem region. Other tRNAs with the same sequence in this region also serve as substrates for the tRNA (adenine-1) methyltransferase.     

Wobble inosine tRNA modification is essential to cell cycle progression in G(1)/S and G(2)/M transitions in fission yeast

Inosine (I) at position 34 (wobble position) of tRNA is formed by the hydrolytic deamination of a genomically encoded adenosine (A). The enzyme catalyzing this reaction, termed tRNA A:34 deaminase, is the heterodimeric Tad2p/ADAT2.Tad3p/ADAT3 complex in eukaryotes. In budding yeast, deletion of each subunit is lethal, indicating that the wobble inosine tRNA modification is essential for viability; however, most of its physiological roles remain unknown. To identify novel cell cycle mutants in fission yeast, we isolated the tad3-1 mutant that is allelic to the tad3(+) gene encoding a homolog of budding yeast Tad3p. Interestingly, the tad3-1 mutant cells principally exhibited cell cycle-specific phenotype, namely temperature-sensitive and irreversible cell cycle arrest both in G(1) and G(2). Further analyses revealed that in the tad3-1 mutant cells, the S257N mutation that occurred in the catalytically inactive Tad3 subunit affected its association with catalytically active Tad2 subunit, leading to an impairment in the A to I conversion at position 34 of tRNA. In tad3-1 mutant cells, the overexpression of the tad3(+) gene completely suppressed the decreased tRNA inosine content. Notably, the overexpression of the tad2(+) gene partially suppressed the temperature-sensitive phenotype and the decreased tRNA inosine content, indicating that the tad3-1 mutant phenotype is because of the insufficient I(34) formation of tRNA. These results suggest that the wobble inosine tRNA modification is essential for cell cycle progression in the G(1)/S and G(2)/M transitions in fission yeast.     

The specificities of yeast methionine aminopeptidase and acetylation of amino-terminal methionine in vivo. Processing of altered iso-1-cytochromes c created by oligonucleotide transformation

The specificities of methionine aminopeptidase and amino-terminal acetylation in the yeast Saccharomyces cerevisiae were investigated in vivo by sequencing a series of altered iso-1-cytochrome c. Twenty iso-1-cytochromes c, each having a different penultimate residue in the sequence Met-Xaa-Phe-Leu-, were created by transforming yeast directly with synthetic oligonucleotides. The degree of methionine cleavage and amino-terminal acetylation was estimated from the levels of pertinent peptides separated by high performance liquid chromatography. The results confirmed our earlier hypothesis (Sherman, F., Stewart, J. W., and Tsunasawa, S. (1985) BioEssays 3, 27-31) that methionine is completely removed from penultimate residues having radii of gyration of 1.29 A or less (glycine, alanine, serine, cysteine, threonine, proline, and valine). However, only partial cleavage occurred in the sequences Met-Thr-Pro-Leu- and Met-Val-Pro-Leu-, demonstrating that proline at the third position inhibits methionine cleavage when the penultimate residue has an intermediate radius of gyration. Acetylation of the retained amino-terminal methionine occurred completely with the Ac-Met-Glu-Phe-Leu- and Ac-Met-Asp-Phe-Leu- sequences and partially with the Ac-Met-Asn-Phe-Leu-sequence. Although the consensus for acetylation of the retained amino-terminal methionine is not completely known, these results and the results of published sequences indicated that Ac-Met-Glu- and Ac-Met-Asp- (methionine followed by an acidic residue) is sufficient for amino-terminal acetylation in eukaryotes but not in prokaryotes.     

Crosslinking of mRNA Analog,pUUAGUAUUUAUU Derivative with Photoactivatable Group at the Guanosine Residue,with Human 80S Ribosomes

Crosslinking of mRNA analog, dodecaribonucleotide pUUAGUAUUUAUU derivative carrying a perfluoroarylazido group at the guanine N7, was studied in model complexes with 80S ribosomes involving tRNA and in binary complex (i.e., in the absence of tRNA). It was shown that, irrespectively of complex formation conditions (13 mM Mg²⁺, or 4 mM Mg²⁺ in the presence of polyamines), the mRNA analog in binary complex with 80S ribosomes was crosslinked with sequence 1840–1849 of 18S rRNA, but in the complexes formed with participation of Phe-tRNA^Phe (where the G residue carrying the arylazido group occupied position –3 to the first nucleotide of the UUU codon at the P site) the analog was crosslinked with nucleotide 1207. The presence and the nature of tRNA at the E site had no effect on the environment of position –3 of the mRNA analog. Efficient crosslinking of the mRNA analog with tRNA was observed in all studied types of complex. Modified codon GUA, when located at the E site, underwent crosslinking with both cognate valine tRNA and noncognate aspartate tRNA for which the extent of binding at the E site of 80S ribosomes was almost the same and depended little on Mg²⁺ concentration and the presence of polyamines.     

In vitro methylation of yeast tRNAAsp by rat brain cortical tRNA-(adenine-1) methyltransferase.

Rat brain cortices from young animals contain large amounts of tRNA (adenine-1)methyltransferase(s). The enzyme(s) can methylate E. coli tRNA and to a lower degree yeast tRNA. Among yeast tRNA species which can be methylated we have selected tRNAAsp as a substrate for the brain enzyme. The digestions of in vitro methylated [Me-3H]-tRNAAsp with pancreatic and/or T1 ribonucleases followed by chromatographies on DEAE-cellulose, 7 M urea, suggested that the methylation of tRNAAsp occurred at a single position within the D-loop. Further digestion of the radioactive oligonucleotide recovered after DEAE-cellulose chromatography by phosphomonoesterase and snake venom phosphodiesterase enzymes followed by bidimensional thin layer chromatography enabled us to determine the location of the adenine residue which becomes methylated by the brain enzyme. This one resulted to be the adenine 14 in the D-loop of yeast tRNAAsp.     

Caenorhabditis elegans ZC376.5 encodes a tRNA (m2/2G(26))dimethyltransferance in which (246)arginine is important for the enzyme activity

It has been estimated that eukaryotes carry more than 50 genes for tRNA modifying enzymes. Of the few so far identified most come from yeast, a lower eukaryote. In Saccharomyces cerevisiae, the TRM1 gene is a nuclear gene encoding the tRNA(m2/ 2G(26))dimethyltransferase, which catalyses the formation of the N2, N2-dimethylguanosine at position 26 in tRNA. We have isolated and characterized the corresponding gene ZC376.5 in Caenorhabditis elegans. Via RTPCR the cDNA sequence of the full length ZC376.5 has now been cloned, expressed in Escherichia coli and demonstrated to encode a tRNA(m2/2G(26))dimethyltransferase that produces dimethyl-G26 in vivo and in vitro with tRNA from yeast and bacteria as substrates. This is the first example of a complete gene sequence coding for a tRNA modifying enzyme from a multicellular organism. A point mutation in exon IV in the C. elegans genome sequence coding for the tRNA(m2/2G(26))methyltransferase that substituted arginine246 for glycine eliminated the modification activity. Exchanging the corresponding lysine residue in the yeast Trm1p for alanine caused a severe loss of activity, indicating that the identity of the amino acid at this position is important for enzyme activity.     

Initial position of aminoacylation of individual Escherichia coli, yeast, and calf liver transfer RNAs.

Transfer RNAs from Escherichia coli, yeast (Sacharomyces cerevisiae), and calf liver were subjected to controlled hydrolysis with venom exonuclease to remove 3'-terminal nucleotides, and then reconstructed successively with cytosine triphosphate (CTP) and 2'- or 3'-deoxyadenosine 5'-triphosphate in the presence of yeast CTP(ATP):tRNA nucleotidyltransferase. The modified tRNAs were purified by chromatography on DBAE-cellulose or acetylated DBAE-cellulose and then utilized in tRNA aminoacylation experiments in the presence of the homologous aminoacyl-tRNA synthetase activities. The E. coli, yeast, and calf liver aminoacyl-tRNA synthetases specific for alanine, glycine, histidine, lysine, serine, and threonine, as well as the E. coli and yeast prolyl-tRNA synthetases and the yeast glutaminyl-tRNA synthetase utilized only those homologous modified tRNAs terminating in 2'-deoxyadenosine (i.e., having an available 3'-OH group). This is interpreted as evidence that these aminoacyl-tRNA synthetases normally aminoacylate their unmodified cognate tRNAs on the 3'-OH group. The aminoacyl-tRNA synthetases from all three sources specific argining, isoleucine, leucine, phenylalanine, and valine, as well as the E. coli and yeast enzymes specific for methionine and the E. coli glutamyl-tRNA synthetase, used as substrates exclusively those tRNAs terminating in 3'-deoxyadenosine. Certain aminoacyl-tRNA synthetases, including the E. coli, yeast, and calf liver asparagine and tyrosine activating enzymes, the E. coli and yeast cysteinyl-tRNA synthetases, and the aspartyl-tRNA synthetase from yeast, utilized both isomeric tRNAs as substrates, although generally not at the same rate. While the calf liver aspartyl- and cysteinyl-tRNA synthetases utilized only the corresponding modified tRNA species terminating in 2'-deoxyadenosine, the use of a more concentrated enzyme preparation might well result in aminoacylation of the isomeric species. The one tRNA for which positional specificity does seem to have changed during evolution is tryptophan, whose E. coli aminoacyl-tRNA synthetase utilized predominantly the cognate tRNA terminating in 3'-deoxyadenosine, while the corresponding yeast and calf liver enzymes were found to utilize predominantly the isomeric tRNAs terminating in 2'-deoxyadenosine. The data presented indicate that while there is considerable diversity in the initial position of aminoacylation of individual tRNA isoacceptors derived from a single source, positional specificity has generally been conserved during the evolution from a prokaryotic to mammalian organism.     

Crosslinking of tRNAs by the carcinostatic agent dirhodium tetraacetate

A crystalline complex of yeast tRNA(phe) and dirhodium tetraacetate (DRTA) was prepared and its X-ray structure determined. The bifunctional DRTA forms an intermolecular cross-link between the N(1) position of adenine A36 in the anticodon triplet and possibly a ribose hydroxyl group of residue A76 at the 3' terminus of a symmetry related tRNA molecule. The rhodium complex apparently shows a preference for binding to the N(1) position of adenine in a single strand region of the tRNA molecule.     

The initiation of haemoglobin synthesis in rabbit reticulocytes

1. The incorporation of labelled valine by rabbit reticulocytes into the N-terminal position of nascent haemoglobin was investigated by deaminating the nascent peptides with nitrous acid and isolating labelled alpha-hydroxyisovaleric acid and valine after acid hydrolysis. 2. The amount of radioactivity in alpha-hydroxyisovaleric acid relative to that in valine indicated the presence of 12.3% N-terminal valine having a free amino group. This high value suggests that most if not all nascent peptides contain valine in the N-terminal position. 3. Cell-free preparations containing reticulocyte ribosomes and pH5 enzymes incorporated alpha-hydroxy-[(14)C]isovaleryl-tRNA (where tRNA refers to transfer RNA), which was obtained by deamination of [(14)C]valyl-tRNA from yeast or liver with nitrous acid, into both soluble and nascent protein. 4. When the soluble protein was chromatographed on CM-cellulose, radioactivity was found to be associated with both the alpha-and beta-globin chains. 5. The kinetics of hydrolysis of [(14)C]valine, was also investigated. Most of the material was hydrolysed rapidly at pH10, but a minor component that was relatively stable appeared to be present to the extent of about 10% of the total valyl-tRNA. Valine was, however, the only hydrolysis product detected by paper chromatography. 6. It is concluded that chain initiation in haemoglobin synthesis involves valine as the N-terminal amino acid and that the amino group of nascent protein is probably not substituted.     

NMR studies of ion binding to Escherichia coli tRNAPhe

The effects of magnesium, spermine, and temperature on the conformation of Escherichia coli tRNAPhe have been examined by proton and phosphorus nuclear magnetic resonance spectroscopy. In the low-field proton NMR spectra we have characterized two slowly interconverting conformations of this tRNA at low magnesium ion concentrations. The relative proportion of the conformers is ion dependent but not ion specific. Magnesium affects protons in all the stems of tRNA while spermine effects are localized near the s4U-8-A-14 and G-15-C-48 tertiary bonds. The effects seen in the proton NMR spectra are compared and correlated with those observed in the phosphorus spectra to give assignments of some of the resolved signals from the phosphate groups. The phosphorus spectra are compared with those of yeast tRNAPhe [Gorenstein, D. G., Goldfield, E. M., Chen, R., Kovar, K., & Luxon, B. A. (1981) Biochemistry 20, 2141; Salemink, P. J. M., Reijerse, E. J., Mollevanger, L., & Hilbers, C. W. (1981) Eur. J. Biochem. 115, 635], and the ion effects are discussed with reference to the magnesium and spermine sites found in the crystal structures of yeast tRNAPhe [Holbrook, S. R., Sussman, J. L., Warrant, R. W., Church, G. M., & Kim, S.-H. (1977) Nucleic Acids Res. 4, 2811; Quigley, G. J., Teeter, M. M., & Rich, A. (1978) Proc. Natl. Acad. Sci. U.S.A. 75, 64; Jack, A., Ladner, J. E., Rhodes, D., Brown, R. S., & Klug, A. (1977) J. Mol. Biol. 111, 315].     

Yeast tRNA Leu UAG. Purification, properties and determination of the nucleotide sequence by radioactive derivative methods.

A second major species of leucine tRNA, tRNA Leu UAG (formerly designated tRNA Leu CUA) was purified from baker's yeast in a three-step procedure entailing BD-cellulose chromatography in the presence and absence of Mg2+ and Sephadex G-100 gel filtration. Results of aminoacylation and partial RNase T1 digestion experiments showed that this tRNA retains a native conformation under conditions that denature yeast tRNA Leu m5CAA (tRNA3 Leu). The primary structure of baker's yeast tRNA Leu UAG was elucidated by application of sensitive radioactive isotope derivative ("postlabeling") methods. Complete RNase T1 and A and partial RNase U2 fragments, prepared from non-radioactive tRNA and 5'-half and 3'-half molecules, were separated by two-dimensional polyethyleneimine-cellulose anion-exchange thin-layer chromatography and isolated by a novel micropreparative procedure affording high yields of these compounds in sufficient purity for subsequent tritium derivative analysis. Base composition and sequence of oligonucleotides were analyzed by tritium derivative methods. Molar ratios of the fragments were determined from the radioactivity of 3H-labeled nucleoside trialcohols in combination with base analysis. 2'-O-Methylated guanosine was characterized using the [gamma-32P]ATP/polynucleotide kinase reaction. The analysis of classical complete and partial RNase digests by the tritium derivative methods yielded the complete nucleotide sequence of the tRNA. A total of about 20 A260 units of the RNA was used for analysis, i.e. considerably less material than required for conventional spectrophotometric analysis. A different sequencing approach, consisting of a combination of "readout sequencing" with tritium sequencing of complete RNase T1 and A fragments, was applied to the 3'-half molecule. The 3'-half molecule was labeled with 32P at its 5' terminus, partially degraded with RNase T1, U2, and Phy1 and with alkali, and subjected to polyacrylamide gel electrophoresis. The sequence was read off the gel on the basis of cleavage patterns and size of the fragments. While the readout procedure provided only the positions of A, U, C, and G residues in the chain, additional information from tritium derivative analysis was utilized to define the positions of the modified nucleosides. The readout sequencing procedure was found to require less than 0.01 A260 unit of RNA and the analysis of the complete fragments about 6 A260 units. Interesting structural features of tRNA Leu UAG are (a) the location of unique, leucine tRNA iso-acceptor-specific sequences next to U-8, a constant nucleotide participating in synthetase recognition, (b) the occurrence of 1-methyladenosine in the T loop, a modification not present in the structurally related tRNA Leu m5CAA, and (c) the unusual presence of an unmodified uridine in the first position of the anticodon, which may be related to the unusual coding properties reported for this tRNA.     

Comparison of the tertiary structure of yeast tRNA(Asp) and tRNA(Phe) in solution. Chemical modification study of the bases

A comparative study of the solution structures of yeast tRNA(Asp) and tRNA(Phe) was undertaken with chemical reagents as structural probes. The reactivity of N-7 positions in guanine and adenine residues was assayed with dimethylsulphate and diethyl-pyrocarbonate, respectively, and that of the N-3 position in cytosine residues with dimethylsulphate. Experiments involved statistical modifications of end-labelled tRNAs, followed by splitting at modified positions. The resulting end-labelled oligonucleotides were resolved on polyacrylamide sequencing gels and analysed by autoradiography. Three different experimental conditions were used to follow the progressive denaturation of the two tRNAs. Experiments were done in parallel on tRNA(Asp) and tRNA(Phe) to enable comparison between the two solution structures and to correlate the results with the crystalline conformations of both molecules. Structural differences were detected for G4, G45, G71 and A21: G4 and A21 are reactive in tRNA(Asp) and protected in tRNA(Phe), while G45 and G71 are protected in tRNA(Asp) and reactive in tRNA(Phe). For the N-7 atom of A21, the different reactivity is correlated with the variable variable loop structures in the two tRNAs; in the case of G45 the results are explained by a different stacking of A9 between G45 and residue 46. For G4 and G71, the differential reactivities are linked to a different stacking in both tRNAs. This observation is of general significance for helical stems. If the previous results could be fully explained by the crystal structures, unexpected similarities in solution were found for N-3 alkylation of C56 in the T-loop, which according to crystallography should be reactive in tRNA(Asp). The apparent discrepancy is due to conformational differences between crystalline and solution tRNA(Asp) at the level of the D and T-loop contacts, linked to long-distance effects induced by the quasi-self-complementary anticodon GUC, which favour duplex formation within the crystal, contrarily to solution conditions where the tRNA is essentially in its free state.