Post-transcriptional modification in archaeal tRNAs: identities and phylogenetic relations of nucleotides from mesophilic and hyperthermophilic Methanococcales.

Post-transcriptional modifications in archaeal RNA are known to be phylogenetically distinct but relatively little is known of tRNA from the Methanococci, a lineage of methanogenic marine euryarchaea that grow over an unusually broad temperature range. Transfer RNAs from Methanococcus vannielii, Methanococcus maripaludis, the thermophile Methanococcus thermolithotrophicus, and hyperthermophiles Methanococcus jannaschii and Methanococcus igneus were studied to determine whether modification patterns reflect the close phylogenetic relationships inferred from small ribosomal subunit RNA sequences, and to examine modification differences associated with temperature of growth. Twenty-four modified nucleosides were characterized, including the complex tricyclic nucleoside wyosine characteristic of position 37 in tRNA(Phe) and known previously only in eukarya, plus two new wye family members of presently unknown structure. The hypermodified nucleoside 5-methylaminomethyl-2-thiouridine, reported previously only in bacterial tRNA at the first position of the anticodon, was identified by liquid chromatography-electrospray ionization mass spectrometry in four of the five organisms. The ribose-methylated nucleosides, 2'-O-methyladenosine, N(2),2'-O-dimethylguanosine and N(2),N(2),2'-O-trimethylguanosine, were found only in hyperthermophile tRNA, consistent with their proposed roles in thermal stabilization of tRNA.

1-Methylguanosine in place of Y base at position 37 in phenylalanine tRNA is responsible for its shiftiness in retroviral ribosomal frameshifting.

Many mammalian retroviruses express their protease and polymerase by ribosomal frameshifting. It was originally proposed that a specialized shifty tRNA promotes the frameshift event. We previously observed that phenylalanine tRNA(Phe) lacking the highly modified wybutoxosine (Y) base on the 3' side of its anticodon stimulated frameshifting, demonstrating that this tRNA is shifty. We now report the shifty tRNA(Phe) contains 1-methylguanosine (m(1)G) in place of Y and that the m(1)G form from rabbit reticulocytes stimulates frameshifting more efficiently than its m(1)G-containing counterpart from mouse neuroblastoma cells. The latter tRNA contains unmodified C and G nucleosides at positions 32 and 34, respectively, while the former tRNA contains the analogous 2'-O-methylated nucleosides at these positions. The data suggest that not only does the loss of a highly modified base from the 3' side of the anticodon render tRNA(Phe) shifty, but the modification status of the entire anticodon loop contributes to the degree of shiftiness. Possible biological consequences of these findings are discussed.

Synthesis and characterization of the native anticodon domain of E. coli TRNA(Lys): simultaneous incorporation of modified nucleosides mnm(5)s(2)U, t(6)A, and pseudouridine using phosphoramidite chemistry.

The anticodon domain of E. coli tRNA(Lys) contains the hypermodified nucleosides mnm(5)s(2)U and t(6)A at positions 34 and 37, respectively, along with a more common psi at position 39. The combination of these three nucleotides represents one of the most extensively modified RNA domains in nature. 2-Cyanoethyl diisopropylphosphoramidites of the hypermodified nucleosides mnm(5)s(2)U and t(6)A were each synthesized with protecting groups suitable for automated RNA oligonucleotide synthesis. The 17 nucleotide anticodon stem-loop of E. coli tRNA(Lys) was then assembled from these synthons using phosphoramidite coupling chemistry. Coupling efficiencies for the two hypermodified nucleosides and for pseudouridine phosphoramidite were all greater than 98%. A mild deprotection scheme was developed to accommodate the highly functionalized RNA. High coupling yields, mild deprotection, and efficient HPLC purification allowed us to obtain 1. 8 mg of purified RNA from a 1 micromol scale RNA synthesis. Our efficient synthetic protocol will allow for biophysical investigation of this rather unique tRNA species wherein nucleoside modification has been shown to play a role in codon-anticodon recognition, tRNA aminoacyl synthetase recognition, and programmed ribosomal frameshifting. The human analogue, tRNA(Lys,3), is the specific tRNA primer for HIV-1 reverse transcriptase and has a similar modification pattern.

Identities and phylogenetic comparisons of posttranscriptional modifications in 16 S ribosomal RNA from Haloferax volcanii.

Small subunit (16 S) rRNA from the archaeon Haloferax volcanii, for which sites of modification were previously reported, was examined using mass spectrometry. A census of all modified residues was taken by liquid chromatography/electrospray ionization-mass spectrometry analysis of a total nucleoside digest of the rRNA. Following rRNA hydrolysis by RNase T(1), accurate molecular mass values of oligonucleotide products were measured using liquid chromatography/electrospray ionization-mass spectrometry and compared with values predicted from the corresponding gene sequence. Three modified nucleosides, distributed over four conserved sites in the decoding region of the molecule, were characterized: 3-(3-amino-3-carboxypropyl)uridine-966, N(6)-methyladenosine-1501, and N(6),N(6)-dimethyladenosine-1518 and -1519 (all Escherichia coli numbering). Nucleoside 3-(3-amino-3-carboxypropyl)uridine, previously unknown in rRNA, occurs at a highly conserved site of modification in all three evolutionary domains but for which no structural assignment in archaea has been previously reported. Nucleoside N(6)-methyladenosine, not previously placed in archaeal rRNAs, frequently occurs at the analogous location in eukaryotic small subunit rRNA but not in bacteria. H. volcanii small subunit rRNA appears to reflect the phenotypically low modification level in the Crenarchaeota kingdom and is the only cytoplasmic small subunit rRNA shown to lack pseudouridine.

Posttranscriptional modification of transfer RNA in the submarine hyperthermophile Pyrolobus fumarii.

In the RNA of hyperthermophiles, which grow optimally between 80 degrees C and 106 degrees C, posttranscriptional modification has been identified as a leading mechanism of structural stabilization. Particularly in the Archaeal evolutionary domain these modifications are expressed as a structurally diverse array of modification motifs, many of which include ribose methylation. Using mass spectrometric techniques we have examined the posttranscriptional modifications in unfractionated tRNA from the remarkable organism Pyrolobus fumarii, which grows optimally at 106 degrees C, but up to 113 degrees C (Blöchl et al. (1997), Extremophiles, 1, 14-21). Twenty-six modified nucleosides were detected, 11 of which are methylated in ribose. A new RNA nucleoside, 1,2'-O-dimethylguanosine (m1Gm) was characterized and the structure confirmed by chemical synthesis.

Codon reading patterns in Drosophila melanogaster mitochondria based on their tRNA sequences: a unique wobble rule in animal mitochondria.

Mitochondrial (mt) tRNA(Trp), tRNA(Ile), tRNA(Met), tRNA(Ser)GCU, tRNA(Asn)and tRNA(Lys)were purified from Drosophila melanogaster (fruit fly) and their nucleotide sequences were determined. tRNA(Lys)corresponding to both AAA and AAG lysine codons was found to contain the anticodon CUU, C34 at the wobble position being unmodified. tRNA(Met)corresponding to both AUA and AUG methionine codons was found to contain 5-formylcytidine (f(5)C) at the wobble position, although the extent of modification is partial. These results suggest that both C and f(5)C as the wobble bases at the anticodon first position (position 34) can recognize A at the codon third position (position 3) in the fruit fly mt translation system. tRNA(Ser)GCU corresponding to AGU, AGC and AGA serine codons was found to contain unmodified G at the anticodon wobble position, suggesting the utilization of an unconventional G34-A3 base pair during translation. When these tRNA anticodon sequences are compared with those of other animal counterparts, it is concluded that either unmodified C or G at the wobble position can recognize A at the codon third position and that modification from A to t(6)A at position 37, 3'-adjacent to the anticodon, seems to be important for tRNA possessing C34 to recognize A3 in the mRNA in the fruit fly mt translation system.

New techniques for the rapid characterization of oligonucleotides by mass spectrometry.

Recent advances in combined HPLC/electrospray ionization-mass spectrometry provide effective new capabilities for the rapid characterization of oligonucleotides. Accurate mass measurements with errors < 0.3 Da, and determination of base and sugar modification and of nearest neighbor identities, can be routinely carried out on 10-100 component mixtures of RNA or DNA. These procedures are widely applicable in structural and analytical studies involving mixtures of oligonucleotides.

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 RNA Modification Database: 1999 update.

The RNA Modification Database (http://medlib.med.utah.edu/RNAmods/) provides a comprehensive listing of naturally modified nucleosides in RNA. Each file includes: chemical structure; common name and symbol; type(s) of RNA in which found and corresponding phylogenetic distribution; Chemical s registry number and index name; and initial literature citations for structure characterization and chemical synthesis. New features include capability to search database files by name or substructural features, modifications in tmRNA, and links to related data and sites.

Presence and location of modified nucleotides in Escherichia coli tmRNA: structural mimicry with tRNA acceptor branches.

Escherichia coli tmRNA functions uniquely as both tRNA and mRNA and possesses structural elements similar to canonical tRNAs. To test whether this mimicry extends to post-transcriptional modification, the technique of combined liquid chromatography/ electrospray ionization mass spectrometry (LC/ESIMS) and sequence data were used to determine the molecular masses of all oligonucleotides produced by RNase T1 hydrolysis with a mean error of 0.1 Da. Thus, this allowed for the detection, chemical characterization and sequence placement of modified nucleotides which produced a change in mass. Also, chemical modifications were used to locate mass-silent modifications. The native E.coli tmRNA contains two modified nucleosides, 5-methyluridine and pseudouridine. Both modifications are located within the proposed tRNA-like domain, in a seven-nucleotide loop mimicking the conserved sequence of T loops in canonical tRNAs. Although tmRNA acceptor branches (acceptor stem and T stem-loop) utilize different architectural rules than those of canonical tRNAs, their conformations in solution may be very similar. A comparative structural and functional analysis of unmodified tmRNA made by in vitro transcription and native E.coli tmRNA suggests that one or both of these post-transcriptional modifications may be required for optimal stability of the acceptor branch which is needed for efficient aminoacylation.

Applications of mass spectrometry to the characterization of oligonucleotides and nucleic acids.

Mass spectrometry-based techniques continue to undergo active development for applications to nucleic acids, fueled by methods based on electrospray and matrix-assisted laser desorption ionization. In the past two years, notable advances have occurred in multiple interrelated areas, including sequencing techniques for oligonucleotides, approaches to mixture analysis, microscale sample handling and targeted DNA assays, and improvements in instrumentation for greater sensitivity and mass resolution.

A novel wobble rule found in starfish mitochondria. Presence of 7-methylguanosine at the anticodon wobble position expands decoding capability of tRNA.

In the starfish mitochondrial (mt) genome, codons AGA and AGG (in addition to AGU and AGC) have been considered to be translated as serine. There is, however, only a single candidate mt tRNA gene responsible for translating these codons and it has a GCT anticodon sequence, but guanosine at the first position of the anticodon should base pair only with pyrimidines according to the conventional wobble rule. To solve this enigma, the mt tRNA GCUser was purified, and sequence determination in combination with electrospray liquid chromatography/mass spectrometry revealed that 7-methylguanosine is located at the first position of the anticodon. This is the first case in which a tRNA has been found to have 7-methylguanosine at the wobble position. It is suggested that methylation at N-7 of wobbling guanosine endows the tRNA with the capability of forming base pairs with all four nucleotides, A, U, G, and C, and expands the repertoire of codon-anticodon interaction. This finding indicates that a nonuniversal genetic code in starfish has been generated by base modification in the tRNA anticodon.

The RNA modification database--1998.

The RNA modification database provides a comprehensive listing of posttranscriptionally modified nucleosides from RNA, and is maintained as an updated version of the initial printed report [Limbach,P.A., Crain,P.F. and McCloskey,J.A. (1994) Nucleic Acids Res. , 22, 2183-2196]. Information provided for each nucleoside includes: the type of RNA in which it occurs and phylogenetic distribution; common chemical name and symbol; Chemical Abstracts registry number and index name; chemical structure; initial literature citations for structural characterization or occurrence, and for chemical synthesis. The data are available through the World Wide Web at: http://www-medlib.med.utah/RNAmods/RNAmods .html

Biosynthesis of archaeosine, a novel derivative of 7-deazaguanosine specific to archaeal tRNA, proceeds via a pathway involving base replacement on the tRNA polynucleotide chain.

Archaeosine is a novel derivative of 7-deazaguanosine found in transfer RNAs of most organisms exclusively in the archaeal phylogenetic lineage and is present in the D-loop at position 15. We show that this modification is formed by a posttranscriptional base replacement reaction, catalyzed by a new tRNA-guanine transglycosylase (TGT), which has been isolated from Haloferax volcanii and purified nearly to homogeneity. The molecular weight of the enzyme was estimated to be 78 kDa by SDS-gel electrophoresis. The enzyme can insert free 7-cyano-7-deazaguanine (preQ0 base) in vitro at position 15 of an H. volcanii tRNA T7 transcript, replacing the guanine originally located at that position without breakage of the phosphodiester backbone. Since archaeosine base and 7-aminomethyl-7-deazaguanine (preQ1 base) were not incorporated into tRNA by this enzyme, preQ0 base appears to be the actual substrate for the TGT of H. volcanii, a conclusion supported by characterization of preQ0 base in an acid-soluble extract of H. volcanii cells. Thus, this novel TGT in H. volcanii is a key enzyme for the biosynthetic pathway leading to archaeosine in archaeal tRNAs.

The RNA modification database.

The RNA modification database provides a comprehensive listing of posttranscriptionally modified nucleosides from all RNAs, and is maintained as an updated version of the initial printed report [Limbach,P.A., Crain,P.F. and McCloskey,J.A. (1994)Nucleic Acids Res. , 22, 2183-2196]. Information provided for each nucleoside includes: the RNA in which it occurs and phylogenetic distribution; common chemical name and symbol; Chemical Abstracts registry number and index name; chemical structure; initial literature citations for structural characterization or occurrence, and for chemical synthesis. The data are available through the WWW and via anonymous ftp.

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 coli it is present only in tRNAArg. The corresponding tRNA genes all have adenosine at position 34. Using as substrates in vitro T7-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. coli enzyme 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 vitro modification in [18O]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 "identify" nucleoside other than adenosine 34. Likewise, the presence of pseudouridine 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(m) of 2.3 nM for its natural substrate tRNASer (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.

The RNA modification database.

The RNA modification database provides a comprehensive listing of post-transcriptionally modified nucleosides from RNA and is maintained as an updated version of the initial printed report. Information provided includes: type(s) of RNA in which found and phylogenetic distribution; common chemical names and symbols; Chemical Abstracts registry numbers and index names; chemical structures; initial literature citations for structural characterization or occurrence and chemical synthesis. The data are available through the World Wide Web, anonymous ftp or from the authors in printed form.

Structural feature of the initiator tRNA gene from Pyrodictium occultum and the thermal stability of its gene product, tRNA(imet).

Pyrodictium occultum is a hyperthermophilic archaeum that grows optimally at 105 degrees C. To study how tRNA molecules in P occulrum are thermally stabilized, we isolated the initiator tRNA gene from the organism using a synthetic DNA probe of 74 bp containing the known nucleotide sequences that are conserved in archaeal initiator tRNAs. A HindIII fragment of 700 bp containing the Pyrodictium initiator tRNA gene was cloned and sequenced by cycle sequencing. The nucleotide sequence revealed that the Pyrodictium initiator tRNA gene has no introns, and that the 3'CCA terminus is encoded. The tRNA gene also contained a unique TATA-like sequence, AAGCTTATAA, which is likely the promoter proposed for archaeal rRNA genes, 450 bp upstream of the 5' end of the tRNA coding region. In the region adjacent to the 3' end of the tRNA coding region, there was a sig G-C base pair inverted repeat followed by a C-rich sequence like the p-independent transcription termination signal of bacterial genes. The Pyrodictium initiator tRNA sequence predicted from the gene sequence contained all of the nucleotide residues A1, A37, U54, A57, U60, and U72, in addition to three G-C base pairs in the anticodon stem region, which are characteristic of archaeal initiator tRNAs. The melting temperature (Tm) of the unmodified initiator tRNA synthesized in vitro using the cloned tRNA gene as a template was 80 degrees C, which is only two degrees lower than that calculated from the G-C content in the stem regions of the tRNA. In contrast, the Tm of the natural initiator tRNA isolated from P occultum was over 100 degrees C. Analysis of digests of purified Pyrodictium initiator tRNA by means of HPLC-mass spectrometry and [32P] post-labeling, indicated that the tRNA contains a variety of modified nucleosides. These results suggest that the extraordinarily high melting temperature of P occultum tRNA(Met)i is due to posttranscriptional modification.

Evidence for incorporation of intact dietary pyrimidine (but not purine) nucleosides into hepatic RNA.

The absorption and metabolism of dietary nucleic acids have received less attention than those of other organic nutrients, largely because of methodological difficulties. We supplemented the rations of poultry and mice with the edible alga Spirulina platensis, which had been uniformly labeled with 13C by hydroponic culture in 13CO2. The rations were ingested by a hen for 4 wk and by four mice for 6 days; two mice were fed a normal diet and two were fed a nucleic acid-deficient diet. The animals were killed and nucleosides were isolated from hepatic RNA. The isotopic enrichment of all mass isotopomers of the nucleosides was analyzed by selected ion monitoring of the negative chemical ionization mass spectrum and the labeling pattern was deconvoluted by reference to the enrichment pattern of the tracer material. We found a distinct difference in the 13C enrichment pattern between pyrimidine and purine nucleosides; the isotopic enrichment of uniformly labeled [M + 9] isotopomers of pyrimidines exceeded that of purines [M + 10] by > 2 orders of magnitude in the avian nucleic acids and by 7- and 14-fold in the murine nucleic acids. The purines were more enriched in lower mass isotopomers, those less than [M + 3], than the pyrimidines. Our results suggest that large quantities of dietary pyrimidine nucleosides and almost no dietary purine nucleosides are incorporated into hepatic nucleic acids without hydrolytic removal of the ribose moiety. In addition, our results support a potential nutritional role for nucleosides and suggest that pyrimidines are conditionally essential organic nutrients.

Characterization of oligonucleotides and nucleic acids by mass spectrometry.

The continued refinement of two recent methods for producing gas-phase ions, electrospray ionization and matrix-assisted laser desorption ionization, has resulted in new techniques for the rapid characterization of oligonucleotides by mass spectrometry. Using commercially available instruments, molecular mass measurements at the 20-mer level, with errors less than 2 Da, can now be made routinely in less than 15 min. Progress has also been achieved in the development of mass spectrometry for rapid sequencing of oligonucleotides smaller than 25 residues.