Selective changes in methionine tRNA species during development of the posterior silkglands of Bombyx mori.

Transfer RNA with methionine acceptor activity isolated from two distinct physiological stages of the developing posterior silkgland of the silkworm, $\text{Bombyx mori}$, was examined. The tRNA from both stages could be fractionated on benzoylated DEAE-cellulose colum into two iso-accepting species, tRNA₁^Met and tRNA₂^Met. The molar quantity per gland of tRNA₁^Met species, which was also formylatable with the $\text{E. coli}$ enzymes, increased twelve-fold as the gland differentiates to produce a large amount of a single protein, silk-fibroin. Since methionine is not a part of silk-fibroin, the preferential increase in tRNA₁^Met content would reflect the increased biological activity and the rapid rate of protein synthesis during the terminal differentiation of posterior silkgland.     

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.     

Normal and Mutant Glycine Transfer RNAs

THE glycine-specific tRNAs of E. coli can be grouped into three subspecies which are separated by chromatography on benzoylated DEAE cellulose (BDC): tRNA^Gly₁ (GGG), tRNA^Gly₂ (GGA/G) and tRNA^Gly₃ (GGU/C)^1,2. The tRNA^Gly₁ and tRNA^Gly₂ are specified by the genes, glyU and glyT, respectively, which have been located at 55 and 77 minutes on the E. coli chromosome. Suppressors of tryptophan A gene (trpA) missense mutations and partial diploid strains have been used extensively to characterize the glycine tRNA structural genes (Table 1)^1–3. A common property of these suppressor mutations is that the altered tRNA^Gly is no longer aminoacylated at the normal rate by the glycyl tRNA synthetase (GRS). When ordinary loading conditions are used virtually none of the suppressor tRNA species are amino-acylated. These studies have shown that single gene copies are normally present at the glyT and glyU loci.     

Involvement of glycine transfer ribonucleic acids in development of the posterior silk gland of Bombyx mori

Glycine transfer RNAs from the two physiological phases, V-2, the stage of maximum growth, and V-5, the stage of maximum fibroin production, during the development of the posterior silk gland of Bombyx mori were examined. The tRNAs from both phases could be fractionated into two major isoaccepting species on a benzoylated DEAE-cellulose column. No significant qualitative differences were observed among the tRNAs, but the total amount of the isoaccepting species of tRNA^Gly in each gland of V-5 stage was 6-fold higher than the amount of tRNA^Gly in the V-2 gland. The codon recognition properties of the tRNA^Gly species were examined. It was found that tRNA^Gly₁ responded to the copolymer (G:U) preferentially while tRNA^Gly_II recognized the copolymer (A:G). The ratio between the extent of incorporation of labeled glycine from glycyl-tRNA^Gly₁ and glycyl-tRNA^Gly_II into protein in a cell-free system utilizing polysomes from the V-5 glands was similar to the relative abundance of the isoaccepting species present in the glands at that time. It also reflected the ratio between the corresponding codons assigned for glycine based on the sequence analysis of fibroin-mRNA [Suzuki, Y., and Brown, D. D. (1972) J. Mol. Biol.63: 409]. These results suggest that the abundance of tRNA^Gly in the posterior silk gland and the changes in the relative amounts of the isoaccepting species are quite specific for the development of the gland.     

The crystal structure of a Thermus thermophilus tRNA acceptor stem microhelix at 1.6 Å resolution

tRNAs are aminoacylated with the correct amino acid by the cognate aminoacyl-tRNA synthetase. The tRNA/synthetase systems can be divided into two classes: class I and class II. Within class I, the tRNA identity elements that enable the specificity consist of complex sequence and structure motifs, whereas in class II the identity elements are assured by few and simple determinants, which are mostly located in the tRNA acceptor stem.The tRNA^Gly/glycyl-tRNA-synthetase (GlyRS) system is a special case regarding evolutionary aspects. There exist two different types of GlyRS, namely an archaebacterial/human type and an eubacterial type, reflecting the evolutionary divergence within this system. We previously reported the crystal structures of an Escherichia coli and of a human tRNA^Gly acceptor stem microhelix. Here we present the crystal structure of a thermophilic tRNA^Gly aminoacyl stem from Thermus thermophilus at 1.6 Å resolution and provide insight into the RNA geometry and hydration.     

Three Different Missense Suppressor Mutations Affecting the tRNAGGGGly Species of Escherichia coli

The Escherichia coli suppressor mutation, supT, has been shown to cause a C → U substitution in the middle position of the tRNA_GGG^Gly anticodon. This is the same tRNA species that is altered by the glyUsu_AGA mutation studied previously. This finding indicates that the supT mutant tRNA reads the glutamic acid codon, GAG. The supT suppressor has also been converted to a new suppressor, called glyUsu_GAA, which will suppress the GAA mutation, trpA46. The in vivo suppression efficiencies of each of these three missense suppressors has been measured and are as follows: glyUsu_AGA, 3.6%; supT, 1.6%; and glyUsu_GAA, 0.4%. Mistranslation by these mutant glycine tRNA species has no adverse affects on cell growth since cultures possessing the suppressors grow as fast as cells without. The supT tRNA species can be observed as a peak in the profile of glycyl-tRNA fractionated on a RPC-5 chromatographic column, indicating that the mutant tRNA can be aminoacylated with reasonable efficiency. This finding contrasts with previous findings concerning the glyUsu_AGA mutant tRNA which is not significantly aminoacylated under the same conditions.     

Structures of Two Glycyl-tRNAs from <Emphasis Type="Italic">Staphylococcus epidermidis</Emphasis>

S. EPIDERMIDIS contains an unusual species of glycyl-tRNA (tRNA^Gly_I) which does not function in protein synthesis but which is able to participate in peptidoglycan synthesis¹. During sequence analysis it became apparent that the original material contained two distinct iso-accepting species (tRNA^Gly_IA and tRNA^Gly_IB) differing by six base changes and the presence of one additional base in the dihydrouridine loop of tRNA^Gly_IB. Using the techniques developed by Sanger et al.^2–5 the complete sequences of both species have been determined and provide an interesting comparison with published⁶ tRNA structures. A complete account of the sequence analysis will be published elsewhere.     

On the role of an unusual tRNAGly isoacceptor in Staphylococcus aureus

In the available Staphylococcus aureus genomes, four different genes have been annotated to encode tRNA^Gly isoacceptors. Besides their prominent role in protein synthesis, some of them also participate in the formation of pentaglycine bridges during cell wall synthesis. However, until today, it is not known how many and which of them are actually involved in this essential procedure. In the present study we identified, apart from the four annotated tRNA^Gly genes, a putative pseudogene which encodes and expresses an unusual fifth tRNA^Gly isoacceptor in S. aureus (as detected via RT-PCR and subsequent direct sequencing analysis). All the in vitro transcribed tRNA^Gly molecules (including the “pseudogene-encoded” tRNA^Gly) can be efficiently aminoacylated by the recombinant S. aureus glycyl-tRNA synthetase. Furthermore, bioinformatic analysis suggests that the “pseudo”-tRNA^Gly(UCC) identified in the present study and two of the annotated isoacceptors bearing the same anticodon carry specific sequence elements that do not favour the strong interaction with EF-Tu that proteinogenic tRNAs would promote. This observation was verified by the differential capacity of Gly-tRNA^Gly molecules to form ternary complexes with activated S. aureus EF-Tu·GTP. These tRNA^Gly molecules display high sequence similarities with their S. epidermidis orthologs which also actively participate in cell wall synthesis. Both bioinformatic and biochemical data suggest that in S. aureus these three glycylated tRNA^Gly isoacceptors that are weak EF-Tu binders, possibly escape protein synthesis and serve as glycine donors for the formation of pentaglycine bridges that are essential for stabilization of the staphylococcal cell wall.     

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.     

Comparative X-ray structure analysis of human and Escherichia coli tRNA(Gly) acceptor stem microhelices

tRNA identity elements assure the correct aminoacylation of tRNAs by the aminoacyl-tRNA synthetases with the cognate amino acid. The tRNA^Gly/glycyl-tRNA sythetase system is member of the so-called ‘class II system’ in which the tRNA determinants consist of rather simple elements. These are mostly located in the tRNA acceptor stem and in the glycine case additionally the discriminator base at position 73 is required. Within the glycine-tRNA synthetases, the archaebacterial/human and the eubacterial sytems differ with respect to their protein structures and the required tRNA identity elements, suggesting a unique evolutionary divergence.In this study, we present a comparison between the crystal structures of the eubacterial Escherichia coli and the human tRNA^Gly acceptor stem microhelices and their surrounding hydration patterns.     

Effect of selective chemical modification of 4-thiouridine of phenylalanine transfer ribonucleic acid on enzyme recognition

Transformation of 4-thiouridine residues in Escherichia coli transfer ribonucleic acids is achieved under conditions which leave the major bases and the primary structure unaffected. The modifications of 4-thiouridine involve either alteration with N-ethylmaleimide, cyanogen bromide, or hydrogen peroxide, or a photochemical transformation effected by irradiation at 330 nm of tRNA in an organic solvent. These selective modifications were made on unfractionated species (Phe, Leu, fMet, Tyr, and Val) and purified species (Phe, fMet, and Val) of E. coli tRNA with little or no loss in their capacities to be aminoacylated. Of the tRNA species tested, subsequent treatment of 4-thiouridineless-tRNA with sodium borohydride affects only the capacity of tRNA^Phe to be aminoacylated. These observations are consistent with the proposal that the cognate ligase recognition site on tRNA^Phe is situated in the nonhydrogenbonded dihydrouridine loop area of the molecule.     

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.     

Fractionation of Rat Liver tRNA by Reversed-Phase High Performance Liquid Chromatography: Isolation of ISO-tRNAsPro

Abstract

This paper illustrates the fractionation of cytoplasmic transfer ribonucleic acid from rat liver by reversed-phase high performance liquid chromatography using a gradient of acetonitrile/ammonium acetate. The procedure is fast, highly reproducible, and gives an excellent resolution of the numerous tRNA population: about 50 peaks with area peak percentages ranging from 0.001 to 5 can be monitored. Uncharged tRNA preparations exhibited a chromatographic profile different from aminoacylated tRNA, thus suggesting a possible strategy to distinguish between aminoacylated and nonacylated tRNA species. Moreover, a first approach to map the HPLC peaks was attempted by chromatographing preparations of tRNA which had been aminoacylated with individual ³H-labeled aminoacids. Here is reported the case of tRNA^Pro, which gave three well separated radioactive peaks, most likely corresponding to tRNA^Pro isoacceptor species.     

Changes in Rhodopseudomonas sphaeroides isoaccepting phenylalanyl-tRNA species during transitions from chemoheterotrophic to photoheterotrophic growth

A new iso-accepting tRNA^phe from extracts of chemoheterotrophic and photoheterotrophic cells of Rhodopseudomonas sphaeroides has been identified by both BDEAE cellulose and RPC-5 chromatography. Rechromatography of each of the tRNA^phe species in either the acylated or deacylated state shows that they migrate as single homogeneous peaks.In steady-state chemoheterotrophic cultures of R. sphaeroides tRNA _I–II ^phe account for 25–30% of the total phenylalanine accepting activity while in steadystate photoheterotrophic cultures tRNA _I–II ^phe account for no more than 10% of the total phenylalanine accepting activity.During the transition from chemoheterotrophic to photoheterotrophic growth conditions the levels of tRNA _I–II ^phe fall in an exponential manner during the first half of the intracytoplasmic membrane induction period. tRNA _I ^phe then remains at a level 10% that of its steady-state chemoheterotrophic level as long as photoheterotrophic growth conditions remain. tRNA _II ^phe , after dropping to 10% of its former chemoheterotrophic level then returns to a level 50% that of its chemoheterotrophic level as long as photoheterotrophic growth conditions remain.Abbreviations BDEAE benzoylated diethyl amino ethyl - RPC reversed phase chromatography - TCA tricholroacetic acid - ICM intracytoplasmic membrane Submitted by WDS in partial fullfilment of requirements for the M.S. degree     

Functional Interaction Between Release Factor One and P-site Peptidyl-tRNA on the Ribosome

Translation termination at UAG is influenced by the nature of the 5′ flanking codon inEscherichia coli. Readthrough of the stop codon is always higher in a strain with mutant (prfA1) as compared to wild-type (prfA⁺) release factor one (RF1). Isocodons, which differ in the last base and are decoded by the same tRNA species, affect termination at UAG differently in strains with mutant or wild-type RF1. No general preference of the last codon base to favour readthrough or termination can be found. The data suggest that RF1 is sensitive to the nature of the wobble base anticodon-codon interaction at the ribosomal peptidyl-tRNA binding site (P-site). For some isoaccepting P-site tRNAs (tRNA₃^ProversustRNA₂^Pro, tRNA₄^ThrversustRNA_1,3^Thr) the effect is different on mutant and wild-type RF1, suggesting an interaction between RF1 at the aminoacyl-tRNA acceptor site (A-site) and the P-site tRNA itself. The glycine codons GGA (tRNA₂^Gly) and GGG (tRNA_2,3^Gly) at the ribosomal P-site are associated with an almost threefold higher readthrough of UAG than any of the other 42 codons tested, including the glycine codons GGU/C, in a strain with wild-type RF1. This differential response to the glycine codons is lost in the strain with the mutant form of RF1 since readthrough is increased to a similar high level for all four glycine codons. High α-helix propensity of the last amino acid residue at the C-terminal end of the nascent peptide is correlated with an increased termination at UAG. The effect is stronger on mutant compared to wild-type RF1. The data suggest that RF1-mediated termination at UAG is sensitive to the nature of the codon-anticodon interaction of the wobble base, the last amino acid residue of the nascent peptide chain, and the tRNA at the ribosomal P-site.     

Crystal structure of the human tRNA microhelix isoacceptor G9990 at 1.18 Å resolution

The tRNA^Gly/Glycyl-tRNA synthetase system belongs to the so called ‘class II’ in which tRNA identity elements consist of relative few and simple motifs, as compared to ‘class I’ where the tRNA determinants are more complicated and spread over different parts of the tRNA, mostly including the anticodon. The determinants from ‘class II’ although, are located in the aminoacyl stem and sometimes include the discriminator base. There exist predominant structure differences for the Glycyl-tRNA-synthetases and for the tRNA^Gly identity elements comparing eucaryotic/archaebacterial and eubacterial systems.We focus on comparative X-ray structure analysis of tRNA^Gly acceptor stem microhelices from different organisms. Here, we report the X-ray structure of the human tRNA^Gly microhelix isoacceptor G9990 at 1.18 Å resolution. Superposition experiments to another human tRNA^Gly microhelix and a detailed comparison of the RNA hydration patterns show a great number of water molecules with identical positions in both RNAs. This is the first structure comparison of hydration layers from two isoacceptor tRNA microhelices with a naturally occurring base pair exchange.     

Discrimination between aminoacyl groups on su+ 7 tRNA by elongation factor Tu

The su⁺7 nonsense suppressor of Escherichia coli is a mutant tRNA^Trp that can be aminoacylated with either tryptophan or glutamine. We have compared the ternary complexes of glutaminyl and tryptophanyl-su⁺7 tRNA with elongation factor Tu and GTP. Glutaminyl-su⁺7 tRNA binds more strongly than tryptophanyl-su⁺7 tRNA to EF Tu · GTP. The greatest distinction between the two species of the tRNA is seen in their dissociation rates from the complex, which differ by as much as fivefold. The distinction is affected by pH values around neutrality. These results show that EF Tu can distinguish between two aminoacyl-tRNAs which differ only in the aminoacyl group. The implications for the unusual amino acid specificity of su⁺7 tRNA are discussed.     

Evolutionary repair reveals an unexpected role of the tRNA modification m1G37 in aminoacylation

The tRNA modification m¹G37, introduced by the tRNA methyltransferase TrmD, is thought to be essential for growth in bacteria because it suppresses translational frameshift errors at proline codons. However, because bacteria can tolerate high levels of mistranslation, it is unclear why loss of m¹G37 is not tolerated. Here, we addressed this question through experimental evolution of trmD mutant strains of Escherichia coli. Surprisingly, trmD mutant strains were viable even if the m¹G37 modification was completely abolished, and showed rapid recovery of growth rate, mainly via duplication or mutation of the proline-tRNA ligase gene proS. Growth assays and in vitro aminoacylation assays showed that G37-unmodified tRNA^Pro is aminoacylated less efficiently than m¹G37-modified tRNA^Pro, and that growth of trmD mutant strains can be largely restored by single mutations in proS that restore aminoacylation of G37-unmodified tRNA^Pro. These results show that inefficient aminoacylation of tRNA^Pro is the main reason for growth defects observed in trmD mutant strains and that proS may act as a gatekeeper of translational accuracy, preventing the use of error-prone unmodified tRNA^Pro in translation. Our work shows the utility of experimental evolution for uncovering the hidden functions of essential genes and has implications for the development of antibiotics targeting TrmD.     

Transfer RNA Identity Change in Anticodon Variants of E. coli tRNAPhe in Vivo

The anticodon sequence is a major recognition element for most aminoacyl-tRNA synthetases. We investigated the in vivo effects of changing the anticodon on the aminoacylation specificity in the example of E. coli tRNA^Phe. Constructing different anticodon mutants of E. coli tRNA^Phe by site-directed mutagenesis, we isolated 22 anticodon mutant tRNA^Phe; the anticodons corresponded to 16 amino acids and an opal stop codon. To examine whether the mutant tRNAs had changed their amino acid acceptor specificity in vivo, we tested the viability of E. coli strains containing these tRNA^Phe genes in a medium which permitted tRNA induction. Fourteen mutant tRNA genes did not affect host viability. However, eight mutant tRNA genes were toxic to the host and prevented growth, presumably because the anticodon mutants led to translational errors. Many mutant tRNAs which did not affect host viability were not aminoacylated in vivo. Three mutant tRNAs containing anticodon sequences corresponding to lysine (UUU), methionine (CAU) and threonine (UGU) were charged with the amino acid corresponding to their anticodon, but not with phenylalanine. These three tRNAs and tRNA^Phe are located in the same cluster in a sequence similarity dendrogram of total E. coli tRNAs. The results support the idea that such tRNAs arising from in vivo evolution are derived by anticodon change from the same ancestor tRNA.