Dynamics of RNA modification by a multi-site-specific tRNA methyltransferase

In most organisms, the widely conserved 1-methyl-adenosine58 (m¹A₅₈) tRNA modification is catalyzed by an S-adenosyl-L-methionine (SAM)-dependent, site-specific enzyme TrmI. In archaea, TrmI also methylates the adjacent adenine 57, m¹A₅₇ being an obligatory intermediate of 1-methyl-inosine57 formation. To study this multi-site specificity, we used three oligoribonucleotide substrates of Pyrococcus abyssi TrmI (_PabTrmI) containing a fluorescent 2-aminopurine (2-AP) at the two target positions and followed the RNA binding kinetics and methylation reactions by stopped-flow and mass spectrometry. _PabTrmI did not modify 2-AP but methylated the adjacent target adenine. 2-AP seriously impaired the methylation of A₅₇ but not A₅₈, confirming that _PabTrmI methylates efficiently the first adenine of the A₅₇A₅₈A₅₉ sequence. _PabTrmI binding provoked a rapid increase of fluorescence, attributed to base unstacking in the environment of 2-AP. Then, a slow decrease was observed only with 2-AP at position 57 and SAM, suggesting that m¹A₅₈ formation triggers RNA release. A model of the protein–tRNA complex shows both target adenines in proximity of SAM and emphasizes no major tRNA conformational change except base flipping during the reaction. The solvent accessibility of the SAM pocket is not affected by the tRNA, thereby enabling S-adenosyl-L-homocysteine to be replaced by SAM without prior release of monomethylated tRNA.     

Crystal structure of Thermus thermophilus tRNA m1A58 methyltransferase and biophysical characterization of its interaction with tRNA

Methyltransferases from the m¹A₅₈ tRNA methyltransferase (TrmI) family catalyze the S-adenosyl-l-methionine-dependent N₁-methylation of tRNA adenosine 58. The crystal structure of Thermus thermophilus TrmI, in complex with S-adenosyl-l-homocysteine, was determined at 1.7 Å resolution. This structure is closely related to that of Mycobacterium tuberculosis TrmI, and their comparison enabled us to enlighten two grooves in the TrmI structure that are large enough and electrostatically compatible to accommodate one tRNA per face of TrmI tetramer. We have then conducted a biophysical study based on electrospray ionization mass spectrometry, site-directed mutagenesis, and molecular docking. First, we confirmed the tetrameric oligomerization state of TrmI, and we showed that this protein remains tetrameric upon tRNA binding, with formation of complexes involving one to two molecules of tRNA per TrmI tetramer. Second, three key residues for the methylation reaction were identified: the universally conserved D170 and two conserved aromatic residues Y78 and Y194. We then used molecular docking to position a N₉-methyladenine in the active site of TrmI. The N₉-methyladenine snugly fits into the catalytic cleft, where the side chain of D170 acts as a bidentate ligand binding the amino moiety of S-adenosyl-l-methionine and the exocyclic amino group of the adenosine. Y194 interacts with the N₉-methyladenine ring, whereas Y78 can stabilize the sugar ring. From our results, we propose that the conserved residues that form the catalytic cavity (D170, Y78, and Y194) are essential for fashioning an optimized shape of the catalytic pocket.     

The Methyl Group of the N6-Methyl-N6-Threonylcarbamoyladenosine in tRNA of Escherichia coli Modestly Improves the Efficiency of the tRNA

tRNA species that read codons starting with adenosine (A) contain N⁶-threonylcarbamoyladenosine (t⁶A) derivatives adjacent to and 3′ of the anticodons from all organisms. In Escherichia coli there are 12 such tRNA species of which two (tRNA_GGU^Thr1 and tRNA_GGU^Thr3) have the t⁶A derivative N⁶-methyl-N⁶-threonylcarbamoyladenosine (m⁶t⁶A37). We have isolated a mutant of E. coli that lacks the m⁶t⁶A37 in these two tRNA_GGU^Thr species. These tRNA species in the mutant are likely to have t⁶A37 instead of m⁶t⁶A37. We show that the methyl group of m⁶t⁶A37 originates from S-adenosyl-l-methionine and that the gene (tsaA) which most likely encodes tRNA(m⁶t⁶A37)methyltransferase is located at min 4.6 on the E. coli chromosomal map. The growth rate of the cell, the polypeptide chain elongation rate, and the selection of Thr-tRNA_GGU^Thr to the ribosomal A site programmed with either of the cognate codons ACC and ACU were the same for the tsaA1 mutant as for the congenic wild-type strain. The expression of the threonine operon is regulated by an attenuator which contains in its leader mRNA seven ACC codons that are read by these two m⁶t⁶A37-containing tRNA_GGU^Thr species. We show that the tsaA1 mutation resulted in a twofold derepression of this operon, suggesting that the lack of the methyl group of m⁶t⁶A37 in tRNA_GGU^Thr slightly reduces the efficiency of this tRNA to read cognate codon ACC.All tRNA species from the three domains, Archaea, Bacteria, and Eucarya, contain modified nucleosides, which are derivatives of the four nucleosides, adenosine, guanosine, cytidine, and uridine. At present, more than 79 different modified nucleosides from the tRNA of various organisms have been characterized (23). Some of these are present in tRNA from only one domain, but a few are present in the same subset of and at the same position in the tRNAs from all three domains (3). One such conserved group of modified nucleosides is the threonylated adenosine (t⁶A) derivatives. These modified adenosines are present adjacent to and 3′ of the anticodon (position 37) in the subset of tRNAs that reads codons starting with A. The universal presence of t⁶A derivatives suggests that these kinds of modifications may have been present in the tRNA of the progenitor, unless a convergent evolution has occurred. This conservation also suggests that the functions of these modified nucleosides may be principally the same in all organisms.In Escherichia coli, the t⁶A37 derivative N⁶-methyl-N⁶- threonylcarbamoyladenosine (m⁶t⁶A37) is present in only two tRNA species, the tRNA_GGU^Thr species, with the same anticodon (20). Threonine is the precursor in the synthesis of t⁶A (10, 32), and in vitro threonylation requires carbonate and ATP (15, 21). Here we show that the methyl group of m⁶t⁶A37 originates from methionine. So far, no mutant deficient in any t⁶A37 derivative has been characterized. As a first step to elucidate the syntheses of these groups of modified nucleosides and their roles in vivo, we have isolated and characterized a mutant deficient in the synthesis of m⁶t⁶A37. We show that the tsaA gene most likely encodes the tRNA(m⁶t⁶A37)methyltransferase that transfers a methyl group from S-adenosylmethionine (AdoMet) to the two tRNA_GGU^Thr species containing the t⁶A moiety. The tsaA gene was localized to the 4.6 min site on the E. coli chromosome. We also show that the methyl group of m⁶t⁶A37 slightly improves the translational efficiency of the two tRNA_GGU^Thr species.     

Understanding the Sequence Specificity of tRNA Binding to Elongation Factor Tu using tRNA Mutagenesis

Measuring the binding affinities of 42 single-base-pair mutants in the acceptor and TΨC stems of Saccharomyces cerevisiae tRNA^Phe to Thermus thermophilus elongation factor Tu (EF-Tu) revealed that much of the specificity for tRNA occurs at the 49-65, 50-64, and 51-63 base pairs. Introducing the same mutations at the three positions into Escherichia coli tRNA_CAG^Leu resulted in similar changes in binding affinity. Swapping the three pairs from several E. coli tRNAs into yeast tRNA^Phe resulted in chimeras with EF-Tu binding affinities similar to those for the donor tRNA. Finally, analysis of double- and triple-base-pair mutants of tRNA^Phe showed that the thermodynamic contributions at the three sites are additive, permitting reasonably accurate prediction of the EF-Tu binding affinity for all E. coli tRNAs. Thus, it appears that the thermodynamic contributions of three base pairs in the TΨC stem primarily account for tRNA binding specificity to EF-Tu.     

The tRNA Recognition Mechanism of Folate/FAD-dependent tRNA Methyltransferase (TrmFO)

The conserved U54 in tRNA is often modified to 5-methyluridine (m⁵U) and forms a reverse Hoogsteen base pair with A58 that stabilizes the L-shaped tRNA structure. In Gram-positive and some Gram-negative eubacteria, m⁵U54 is produced by folate/FAD-dependent tRNA (m⁵U54) methyltransferase (TrmFO). TrmFO utilizes N⁵,N¹⁰-methylenetetrahydrofolate (CH₂THF) as a methyl donor. We previously reported an in vitro TrmFO assay system, in which unstable [¹⁴C]CH₂THF was supplied from [¹⁴C]serine and tetrahydrofolate by serine hydroxymethyltransferase. In the current study, we have improved the TrmFO assay system by optimization of enzyme and substrate concentrations and introduction of a filter assay system. Using this assay, we have focused on the tRNA recognition mechanism of TrmFO. 42 tRNA mutant variants were prepared, and experiments with truncated tRNA and microhelix RNAs revealed that the minimum requirement of TrmFO exists in the T-arm structure. The positive determinants for TrmFO were found to be the U54U55C56 sequence and G53-C61 base pair. The gel mobility shift assay and fluorescence quenching showed that the affinity of TrmFO for tRNA in the initial binding process is weak. The inhibition experiments showed that the methylated tRNA is released before the structural change process. Furthermore, we found that A38 prevents incorrect methylation of U32 in the anticodon loop. Moreover, the m¹A58 modification clearly accelerates the TrmFO reaction, suggesting a synergistic effect of the m⁵U54, m¹A58, and s²U54 modifications on m⁵s²U54 formation in Thermus thermophilus cells. The docking model of TrmFO and the T-arm showed that the G53-C61 base pair is not able to directly contact the enzyme.     

The yfiC gene of E. coli encodes an adenine-N6 methyltransferase that specifically modifies A37 of tRNA1Val(cmo5UAC)

Transfer RNA is highly modified. Nucleotide 37 of the anticodon loop is represented by various modified nucleotides. In Escherichia coli, the valine-specific tRNA (cmo⁵UAC) contains a unique modification, N⁶-methyladenosine, at position 37; however, the enzyme responsible for this modification is unknown. Here we demonstrate that the yfiC gene of E. coli encodes an enzyme responsible for the methylation of A37 in tRNA₁^Val. Inactivation of yfiC gene abolishes m⁶A formation in tRNA₁^Val, while expression of the yfiC gene from a plasmid restores the modification. Additionally, unmodified tRNA₁^Val can be methylated by recombinant YfiC protein in vitro. Although the methylation of m⁶A in tRNA₁^Val by YfiC has little influence on the cell growth under standard conditions, the yfiC gene confers a growth advantage under conditions of osmotic and oxidative stress.     

New chromatographic and biochemical strategies for quick preparative isolation of tRNA

A combination of hydrophobic chromatography on phenyl-Sepharose and reversed phase HPLC was used to purify individual tRNAs with high specific activity. The efficiency of chromatographic separation was enhanced by biochemical manipulations of the tRNA molecule, such as aminoacylation, formylation of the aminoacyl moiety and enzymatic deacylation. Optimal combinations are presented for three different cases. (i) tRNA^Phe from Escherichia coli. This species was isolated by a combination of low pressure phenyl-Sepharose hydrophobic chromatography with RP-HPLC. (ii) tRNA^Ile from E.coli. Aminoacylation increases the retention time for this tRNA in RP-HPLC. The recovered acylated intermediate is deacylated by reversion of the aminoacylation reaction and submitted to a second RP-HPLC run, in which deacylated tRNA^Ile is recovered with high specific activity. (iii) tRNA_i^Met from Saccharomyces cerevisiae. The aminoacylated form of this tRNA is unstable. To increase stability, the aminoacylated form was formylated using E.coli enzymes and, after one RP-HPLC step, the formylated derivative was deacylated using peptidyl-tRNA hydrolase from E.coli. The tRNA_i^Met recovered after a second RP-HPLC run exhibited electrophoretic homogeneity and high specific activity upon aminoacylation. These combinations of chromatographic separation and biochemical modification can be readily adapted to the large-scale isolation of any particular tRNA.     

Isolation and chromatographic behaviour of phenylalanine tRNA from barley embryos

Two fractions of phenylalanine tRNA (tRNA^Phe₁ and tRNA^Phe₂) were purified by BD-cellulose and RPC-5 chromatography of crude tRNA isolated from barley embryos. Successive RPC-5 rechromatography runs of tRNA^Phe₂ showed its conversion into more stable tRNA^Phe₁, suggesting that the two fractions have essentially the same primary structure. Both tRNA^Phe₁ and tRNA^Phe₂ had about the same acceptor activity, but tRNA^Phe₂ was aminoacylated much faster than tRNA^Phe₁. RPC-5 chromatography of crude aminoacylated tRNA showed higher contents of phe-tRNA^Phe₂ than of phe-tRNA^Phe₁ but the ratio of these two fractions estimated by relative fluorescence intensity was about 1. Fluorescence spectra of tRNA^Phe from barley embryos suggest that it contains Y base similar to Y_w from wheat tRNA^Phe.     

Escherichia coli formylmethionine tRNA: methylation of specific guanine and adenine residues catalyzed by HeLa cells tRNA methylases and the effect of these methylations on its biological properties

Purified HeLa cell tRNA methylases have been used for site-specific methylations of Escherichia coli formylmethionine transfer ribonucleic acid (tRNA^fMet). Guanine-N²-methylase catalyzed the methylation of a specific guanine residue (G₂₇) and adenine-1-methylase that of a specific adenine residue (A₅₉). The combined action of both of these enzymes leads to a total incorporation of two methyl groups and results in the methylation of both G₂₇ and A₅₉.The effect of introducing additional methyl groups on the function of tRNA has been studied by a comparison in vitro of the biological properties of tRNA^fMet and enzymically methylated tRNA^fMet. It was found that none of the following properties of E. coli tRNA^fMet are altered to any significant extent by methylation: (a) rate, extent, and specificity of aminoacylation, (b) ability of methionyl-tRNA to be enzymically formylated, and (c) ability of formylmethionyl-tRNA to initiate protein synthesis in cell-free extracts of E. coli in the presence of f2 RNA as messenger. Also, the temperature versus absorbance profile of the doubly methylated tRNA^fmet was virtually identical to that of the E. coli tRNA^fMet, and enzymically methylated tRNA^fmet resembled tRNA^fMet in that both were resistant to deacylation by E. coli, N-acylaminoacyl-tRNA hydrolase.     

A primordial RNA modification enzyme: the case of tRNA (m1A) methyltransferase

The modified nucleoside 1-methyladenosine (m¹A) is found in the T-loop of many tRNAs from organisms belonging to the three domains of life (Eukaryota, Bacteria, Archaea). In the T-loop of eukaryotic and bacterial tRNAs, m¹A is present at position 58, whereas in archaeal tRNAs it is present at position(s) 58 and/or 57, m¹A57 being the obligatory intermediate in the biosynthesis of 1-methylinosine (m¹I57). In yeast, the formation of m¹A58 is catalysed by the essential tRNA (m¹A58) methyltransferase (MTase), a tetrameric enzyme that is composed of two types of subunits (Gcd14p and Gcd10p), whereas in the bacterium Thermus thermophilus the enzyme is a homotetramer of the TrmI polypeptide. Here, we report that the TrmI enzyme from the archaeon Pyrococcus abyssi is also a homotetramer. However, unlike the bacterial site-specific TrmI MTase, the P.abyssi enzyme is region-specific and catalyses the formation of m¹A at two adjacent positions (57 and 58) in the T-loop of certain tRNAs. The stabilisation of P.abyssi TrmI at extreme temperatures involves intersubunit disulphide bridges that reinforce the tetrameric oligomerisation, as revealed by biochemical and crystallographic evidences. The origin and evolution of m¹A MTases is discussed in the context of different hypotheses of the tree of life.     

Ternary complex between elongation factor Tu•GTP and Phe-tRNA

The effect of aminoacylation and ternary complex formation with elongation factor Tu•GTP on the tertiary structure of yeast tRNA^Phe was examined by ¹H-NMR spectroscopy. Esterification of phenylalanine to tRNA^Phe does not lead to changes with respect to the secondary and tertiary base pair interactions of tRNA. Complex formation of Phe-tRNA^Phe with elongation factor Tu•GTP results in a broadening of all imino proton resonances of the tRNA. The chemical shifts of several NH proton resonances are slightly changed as compared to free tRNA, indicating a minor conformational rearrangement of Phe-tRNA^Phe upon binding to elongation factor Tu•GTP. All NH proton resonances corresponding to the secondary and tertiary base pairs of tRNA, except those arising from the first three base pairs in the aminoacyl stem, are detectable in the Phe-tRNA^Phe•elongation factor Tu•GTP ternary complex. Thus, although the interactions between elongation factor Tu and tRNA accelerate the rate of NH proton exchange in the aminoacyl stem-region, the Phe-tRNA^Phe preserves its typical L-shaped tertiary structure in the complex. At high (> 10⁻⁴ M) ligand concentrations a complex between tRNA^Phe and elongation factor Tu•GDP can be detected on the NMR time-scale. Formation of this complex is inhibited by the presence of any RNA not related to the tRNA structure. Using the known tertiary structures of yeast tRNA^Phe and Thermus thermophilus elongation factor Tu in its active, GTP form, a model of the ternary complex was constructed.     

N7-Methylguanine at position 46 (m7G46) in tRNA from Thermus thermophilus is required for cell viability at high temperatures through a tRNA modification network

N⁷-methylguanine at position 46 (m⁷G46) in tRNA is produced by tRNA (m⁷G46) methyltransferase (TrmB). To clarify the role of this modification, we made a trmB gene disruptant (ΔtrmB) of Thermus thermophilus, an extreme thermophilic eubacterium. The absence of TrmB activity in cell extract from the ΔtrmB strain and the lack of the m⁷G46 modification in tRNA^Phe were confirmed by enzyme assay, nucleoside analysis and RNA sequencing. When the ΔtrmB strain was cultured at high temperatures, several modified nucleotides in tRNA were hypo-modified in addition to the lack of the m⁷G46 modification. Assays with tRNA modification enzymes revealed hypo-modifications of Gm18 and m¹G37, suggesting that the m⁷G46 positively affects their formations. Although the lack of the m⁷G46 modification and the hypo-modifications do not affect the Phe charging activity of tRNA^Phe, they cause a decrease in melting temperature of class I tRNA and degradation of tRNA^Phe and tRNA^Ile. ³⁵S-Met incorporation into proteins revealed that protein synthesis in ΔtrmB cells is depressed above 70°C. At 80°C, the ΔtrmB strain exhibits a severe growth defect. Thus, the m⁷G46 modification is required for cell viability at high temperatures via a tRNA modification network, in which the m⁷G46 modification supports introduction of other modifications.     

Mature methyl-deficient tRNA isolated from a mammary adenocarcinoma

A transplantable rat tumor, mammary adenocarcinoma 13762, accumulates tRNA which can be methylated in vitro by mammalian tRNA (adenine-1) methyltransferase. This unusual ability of the tumor RNA to serve as substrate for a homologous tRNA methylating enzyme is correlated with unusually low levels of the A₅₈-specific adenine-1 methyltransferase. The nature of the methyl-accepting RNA has been examined by separating tumor tRNA on two-dimensional polyacrylamide gels. Comparisons of ethidium bromide-stained gels of tumor vs. liver tRNA show no significant quantitative differences and no accumulation of novel tRNAs or precursor tRNAs in adenocarcinoma RNA. Two-dimensional separations of tumor RNA after in vitro [¹⁴C]methylation using purified adenine-1 methyltransferase indicate that about 25% of the tRNA species are strongly methyl-accepting RNAs. Identification of six of the tRNAs separated on two-dimensional gels has been carried out by hybridization of cloned tRNA genes to Northern blots. Three of these, tRNA^Lys3, tRNA^Gln and tRNA^Met_i, are among the adenocarcinoma methyl-accepting RNAs. The other three RNAs, all of which are leucine-specific tRNAs, show no methyl-accepting properties. Our results suggest that low levels of a tRNA methyltransferase in the adenocarcinoma cause selected species of tRNA to escape the normal A₅₈ methylation, resulting in the appearance of several mature tRNAs which are deficient in 1-methyladenine. The methyl-accepting tRNAs from the tumor appear as ethidium bromide-stained spots of similar intensity to those seen for RNA from rat liver; therefore, methyladenine deficiency does not seem to impair processing of these tRNAs.     

Classical molecular dynamics simulation of seryl tRNA synthetase and threonyl tRNA synthetase bound with tRNA and aminoacyl adenylate

Lacunae of understanding exist concerning the active site organization during the charging step of the aminoacylation reaction. We present here a molecular dynamics simulation study of the dynamics of the active site organization during charging step of subclass IIa dimeric SerRS from Thermus thermophilus (^ttSerRS) bound with ^tttRNA^Ser and dimeric ThrRS from Escherichia coli (^ecThrRS) bound with ^ectRNA^Thr. The interactions between the catalytically important loops and tRNA contribute to the change in dynamics of tRNA in free and bound states, respectively. These interactions help in the development of catalytically effective organization of the active site. The A76 end of the ^tttRNA^Ser exhibits fast dynamics in free State, which is significantly slowed down within the active site bound with adenylate. The loops change their conformation via multimodal dynamics (a slow diffusive mode of nanosecond time scale and fast librational mode of dynamics in picosecond time scale). The active site residues of the motif 2 loop approach the proximal bases of tRNA and adenylate by slow diffusive motion (in nanosecond time scale) and make conformational changes of the respective side chains via ultrafast librational motion to develop precise hydrogen bond geometry. Presence of bound Mg²⁺ ions around tRNA and dynamically slow bound water are other common features of both aaRSs. The presence of dynamically rigid Zinc ion coordination sphere and bipartite mode of recognition of ^ectRNA^Thr are observed.     

Crystal structure of a human tRNA(Gly) microhelix at 1.2A resolution

The tRNA^Gly/glycyl-tRNA synthetase (GlyRS) system belongs to the so-called ‘class II aminoacyl-tRNA synthetase system’ in which tRNA identity elements are assured by rather few and simple determinants mostly located in the tRNA acceptor stem. Regarding evolutionary aspects, the tRNA^Gly/GlyRS system is a special case. There exist two different types of GlyRS, namely an archaebacterial/human type and a eubacterial type reflecting an evolutionary divergence within this system.Here we report the crystal structure of a human tRNA^Gly acceptor stem microhelix at 1.2 Å resolution. The local geometric parameters of the microhelix and the water network surrounding the RNA are presented. The structure complements the previously published Escherichia coli tRNA^Gly aminoacyl stem structure.     

N2-guanine specific transfer RNA methyltransferase II from rat liver

An enzyme was purified from rat liver and leukemic rat spleen which methylates guanosine residues in tRNA to N²-methylguanosine. By sequence analysis of bulk E. coli tRNA methylated with crude extracts it was shown that the enzyme is responsible for about 50% of total m²G formed invitro. The extent of methylation of a number of homogenous tRNA species was measured using the purified enzyme from both sources. Among tested E. coli tRNAs only tRNA^Arg, tRNA^Phe, and tRNA^Val yielded significantly more m²G than the bulk tRNA. The K_m for tRNA^Arg in the methylation reaction with enzymes from either tissue was 7.8 × 10⁻⁷ M as compared to the value 1 × 10⁻⁵ M obtained for the bulk tRNA. In a pancreatic RNase digest of bulk tRNA as well as of pure tRNA^Arg, tRNA^Phe, and tRNA^Val, A-m²G-Cp was found to be the only sequence methylated. Thus, the mammalian methyltransferase specifically recognizes the guanylate residue at position 10 from the 5′-end contained in a sequence (s⁴)U-A-G-Cp. Furthermore, there is no change between the enzyme from normal liver and leukemic spleen in the affinity for tRNA, the methylating capacity, and tRNA site and sequence recognition specificity.     

Crystal structure of tRNA m1A58 methyltransferase TrmI from Aquifex aeolicus in complex with S-adenosyl-l-methionine

The N ¹-methyladenosine residue at position 58 of tRNA is found in the three domains of life, and contributes to the stability of the three-dimensional L-shaped tRNA structure. In thermophilic bacteria, this modification is important for thermal adaptation, and is catalyzed by the tRNA m¹A58 methyltransferase TrmI, using S-adenosyl-l-methionine (AdoMet) as the methyl donor. We present the 2.2 Å crystal structure of TrmI from the extremely thermophilic bacterium Aquifex aeolicus, in complex with AdoMet. There are four molecules per asymmetric unit, and they form a tetramer. Based on a comparison of the AdoMet binding mode of A. aeolicus TrmI to those of the Thermus thermophilus and Pyrococcus abyssi TrmIs, we discuss their similarities and differences. Although the binding modes to the N6 amino group of the adenine moiety of AdoMet are similar, using the side chains of acidic residues as well as hydrogen bonds, the positions of the amino acid residues involved in binding are diverse among the TrmIs from A. aeolicus, T. thermophilus, and P. abyssi.     

Analysis of genomic tRNA revealed presence of novel genomic features in cyanobacterial tRNA

Transfer RNAs (tRNA) are important molecules that involved in protein translation machinery and acts as a bridge between the ribosome and codon of the mRNA. The study of tRNA is evolving considerably in the fields of bacteria, plants, and animals. However, detailed genomic study of the cyanobacterial tRNA is lacking. Therefore, we conducted a study of cyanobacterial tRNA from 61 species. Analysis revealed that; cyanobacteria contain thirty-six to seventy-eight tRNA gens per genome that encodes for 20 tRNA isotypes. The number of iso-acceptors (anti-codons) ranged from thirty-two to forty-three per genome. tRNA^Ile with anti-codon AAU, GAU, and UAU was reported to be absent from the genome of Gleocapsa PCC 73,106 and Xenococcus sp. PCC 7305. Instead, they were contained anti-codon CAU that is common to tRNA^Met and tRNA^Ile as well. The iso-acceptors ACA (tRNA^Cys), ACC (tRNA^Gly), AGA, ACU (tRNA^Ser), AAA (tRNA^Phe), AGG (tRNA^Pro), AAC (tRNA^Val), GCG (tRNA^Arg), AUG (tRNA^His), and AUC (tRNA^Asp) were absent from the genome of cyanobacterial lineages studied so far. A few of the cyanobacterial species encode suppressor tRNAs, whereas none of the species were found to encode a selenocysteine iso-acceptor. Cyanobacterial species encode a few putative novel tRNAs whose functions are yet to be elucidated.