Fluorescence-monitored conformational change on the 3'-end of tRNA upon aminoacylation.

Fluorescent tRNAs species with formycine in the 3'-terminal position (tRNA-CCF) were derived from Escherichia coli tRNA(Val). Thermus thermophilus tRNA(Aap) and Thermus thermophilus tRNA(Phe). The fluorescence of formycine was used to monitor the conformational changes at the 3'-terminus of tRNA caused by aminoacylation and hydrolysis of aminoacyl residue from aminoacyl-tRNAs. An increase of about 15% in the fluorescence intensity was observed after aminoacylation of the three tRNA-CCF. This change in fluorescence amplitude that is reversed by hydrolysis of the aminoacyl residue, does not depend on the structure of the amino acid or tRNA sequence. A local conformational change at the 3'-terminal formycine probably involving a partial destacking of the base moiety in the ACCF end takes place as a consequence of aminoacylation. A structural change at the 3'-terminus of tRNA induced by attachment and detachment of the acyl residue may be important in controlling the substrate/product relationship in reactions in which tRNA participates during protein biosynthesis.     

An engineered class I transfer RNA with a class II tertiary fold

Structure-based engineering of the tertiary fold of Escherichia coli tRNA(Gln)2 has enabled conversion of this transfer RNA to a class II structure while retaining recognition properties of a class I glutamine tRNA. The new tRNA possesses the 20-nt variable stem-loop of Thermus thermophilus tRNA(Ser). Enlargement of the D-loop appears essential to maintaining a stable tertiary structure in this species, while rearrangement of a base triple in the augmented D-stem is critical for efficient glutaminylation. These data provide new insight into structural determinants distinguishing the class I and class II tRNA folds, and demonstrate a marked sensitivity of glutaminyl-tRNA synthetase to alteration of tRNA tertiary structure.     

Unilateral aminoacylation specificity between bovine mitochondria and eubacteria

The present study shows unilateral aminoacylation specificity between bovine mitochondria and eubacteria (Escherichia coli and Thermus thermophilus) in five amino acid-specific aminoacylation systems. Mitochondrial synthetases were capable of charging eubacterial tRNA as well as mitochondrial tRNA, whereas eubacterial synthetases did not efficiently charge mitochondrial tRNA. Mitochondrial phenylalanyl-, threonyl-, arginyl-, and lysyl-tRNA synthetases were shown to charge and discriminate cognate E. coli tRNA species from noncognate ones strictly, as did the corresponding E. coli synthetases. By contrast, mitochondrial seryl-tRNA synthetase not only charged cognate E. coli serine tRNA species but also extensively misacylated noncognate E. coli tRNA species. These results suggest a certain conservation of tRNA recognition mechanisms between the mitochondrial and E. coli aminoacyl-tRNA synthetases in that anticodon sequences are most likely to be recognized by the former four synthetases, but not sufficiently by the seryl-tRNA synthetase. The unilaterality in aminoacylation may imply that tRNA recognition mechanisms of the mitochondrial synthetases have evolved to be, to some extent, simpler than their eubacterial counterparts in response to simplifications in the species-number and the structural elements of animal mitochondrial tRNAs.     

The open reading frame TTC1157 of Thermus thermophilus HB27 encodes the methyltransferase forming N²-methylguanosine at position 6 in tRNA

N(2)-methylguanosine (m(2)G) is found at position 6 in the acceptor stem of Thermus thermophilus tRNA(Phe). In this article, we describe the cloning, expression, and characterization of the T. thermophilus HB27 methyltransferase (MTase) encoded by the TTC1157 open reading frame that catalyzes the formation of this modified nucleoside. S-adenosyl-L-methionine is used as donor of the methyl group. The enzyme behaves as a monomer in solution. It contains an N-terminal THUMP domain predicted to bind RNA and contains a C-terminal Rossmann-fold methyltransferase (RFM) domain predicted to be responsible for catalysis. We propose to rename the TTC1157 gene trmN and the corresponding protein TrmN, according to the bacterial nomenclature of tRNA methyltransferases. Inactivation of the trmN gene in the T. thermophilus HB27 chromosome led to a total absence of m(2)G in tRNA but did not affect cell growth or the formation of other modified nucleosides in tRNA(Phe). Archaeal homologs of TrmN were identified and characterized. These proteins catalyze the same reaction as TrmN from T. thermophilus. Individual THUMP and RFM domains of PF1002 from Pyrococcus furiosus were produced. These separate domains were inactive and did not bind tRNA, reinforcing the idea that the THUMP domain acts in concert with the catalytic domain to target a particular position of the tRNA molecule.     

Thermus thermophilus contains an eubacterial and an archaebacterial aspartyl-tRNA synthetase

Thermus thermophilus possesses two aspartyl-tRNA synthetases (AspRSs), AspRS1 and AspRS2, encoded by distinct genes. Alignment of the protein sequences with AspRSs of other origins reveals that AspRS1 possesses the structural features of eubacterial AspRSs, whereas AspRS2 is structurally related to the archaebacterial AspRSs. The structural dissimilarity between the two thermophilic AspRSs is correlated with functional divergences. AspRS1 aspartylates tRNA(Asp) whereas AspRS2 aspartylates tRNA(Asp), and tRNA(Asn) with similar efficiencies. Since Asp bound on tRNA(Asn) is converted into Asn by a tRNA-dependent aspartate amidotransferase, AspRS2 is involved in Asn-tRNA(Asn) formation. These properties relate functionally AspRS2 to archaebacterial AspRSs. The structural basis of the dual specificity of T. thermophilus tRNA(Asn) was investigated by comparing its sequence with those of tRNA(Asp) and tRNA(Asn) of strict specificity. It is shown that the thermophilic tRNA(Asn) contains the elements defining asparagine identity in Escherichia coli, part of which being also the major elements of aspartate identity, whereas minor elements of this identity are missing. The structural context that permits expression of aspartate and asparagine identities by tRNA(Asn) and how AspRS2 accommodates tRNA(Asp) and tRNA(Asn) will be discussed. This work establishes a distinct structure-function relationship of eubacterial and archaebacterial AspRSs. The structural and functional properties of the two thermophilic AspRSs will be discussed in the context of the modern and primitive pathways of tRNA aspartylation and asparaginylation and related to the phylogenetic connexion of T. thermophilus to eubacteria and archaebacteria.     

Genetic and molecular analysis of the tRNA-tufB operon of the myxobacterium Stigmatella aurantiaca.

The tufB gene, encoding elongation factor Tu (EF-Tu), from the myxobacterium Stigmatella aurantiaca was cloned and sequenced. It is preceded by four tRNA genes, the first ever described in myxobacteria. The tRNA synthesized from these genes and the general organization of the locus seem identical to that of Escherichia coli, but differences of potential importance were found in the tRNA sequences and in the intergenic regions. The primary structure of EF-Tu was deduced from the tufB DNA sequence. The factor is composed of 396 amino acids, with a predicted molecular mass of 43.4 kDa, which was confirmed by expression of tufB in maxicells. Sequence comparisons between S.aurantiaca EF-Tu and other bacterial homologues from E.coli, Salmonella typhimurium and Thermus thermophilus displayed extensive homologies (75.9%). Among the variable positions, two Cys residues probably involved in the temperature sensitivity of E.coli and S.typhimurium EF-Tu are replaced in T.thermophilus and S.aurantiaca EF-Tu. Since two or even three tuf genes have been described in other bacterial species, the presence of multiple tuf genes was sought for. Southern and Northern analysis are consistent with two tuf genes in the genome of S.aurantiaca. Primer extension experiments indicate that the four tRNA genes and tufB are organized in a single operon.     

Nucleotide sequence of formylmethionine tRNA from an extreme thermophile, Thermus thermophilus HB8.

The nucleotide sequence of formylmethionine tRNA from an extreme thermophile, Thermus thermophilus HB8, was determined by a combination of classical methods using unlabeled samples to determine the sequences of the oligonucleotides of RNase T1 and RNase A digests and a rapid sequencing gel technique using 5'-32P labeled samples to determine overlapping sequences. Formylmethionine tRNA from T. thermophilus is composed of two species, tRNAf1Met and tRNAf2Met. Their nucleotide sequences are almost identical, and are also almost identical with that of E. coli tRNAfMet, except for slight modifications and replacements. Both species have modifications at three points which do not exist in E. coli tRNAfMet: 2'-O-methylation at G19, N-1-methylation at A59 and 2-thiolation at T55. Moreover U51 in E. coli tRNAfMet is replaced by C51 in both species, so that a G-C pair is formed between this C51 and G65. tRNAf2Met has a reversed G-C pair at positions 52 and 64 compared with those in tRNAf1Met and E. coli tRNAfMet. Other regions are mostly the same as those in all prokaryotic initiator tRNAs so far reported. The thermostability of these thermophile initiator tRNAs is discussed in relation to their unique modifications.     

Identification of Thermus thermophilus HB8 tRNA (Gm18) methyltransferase gene.

For the purpose of identification of the gene for Thermus thermophilus tRNA (Gm18) methyltransferase [tRNA (guanosine-2'-)-methyltransferase, EC 2.1.1.34], the purified enzyme from native source was analyzed by the peptide-mass mapping. The target gene encoded the amino acid sequences of the obtained peptides was searched in data from Thermus thermophilus HB8 genome-sequencing project. We found the target gene AB05130, which was expected to encode a protein composed of 194 amino acid residues and the molecular mass of this protein was calculated as 22083. The recombinant protein was expressed in E. coli as an active form. The Gm18 formation activity of the purified recombinant protein was confirmed by in vitro methylation followed by two-dimensional thin layer chromatography and Liquid Chromatography/Mass Spectrum analysis of substrate tRNA.     

Conformational changes of aminoacyl-tRNA and uncharged tRNA upon complex formation with polypeptide chain elongation factor Tu

The conformation change of Thermus thermophilus tRNA(1Ile) upon complex formation with T. thermophilus elongation factor Tu (EF-Tu) was studied by analysis of the circular dichroism (CD) bands at 315 nm (due to the 2-thioribothymidine residue in the T-loop) and at 295 nm (due to the core structure of tRNA). Formation of the ternary complex of isoleucyl-tRNA(1Ile) and EF-Tu.GTP increased the intensities of these CD bands, indicating stabilization of the association between the T-loop and the D-loop and also a significant conformation change of the core region. Upon complex formation of EF-Tu.GTP and uncharged tRNA, however, the conformation of the core region is not changed, while the association of the two loops is still stabilized. On the other hand, the binding with EF-Tu.GDP does not appreciably affect the conformation of isoleucyl-tRNA or uncharged tRNA. These indicate the importance of the gamma-phosphate group of GTP and the aminoacyl group in the formation of the active complex of aminoacyl-tRNA and EF-Tu.GTP.     

Antideterminants present in minihelix(Sec) hinder its recognition by prokaryotic elongation factor Tu.

During protein biosynthesis, all aminoacylated elongator tRNAs except selenocysteine-inserting tRNA Sec form ternary complexes with activated elongation factor. tRNA Sec is bound by its own translation factor, an elongation factor analogue, e.g. the SELB factor in prokaryotes. An apparent reason for this discrimination could be related to the unusual length of tRNA Sec amino acid-acceptor branch formed by 13 bp. However, it has been recently shown that an aspartylated minihelix of 13 bp derived from yeast tRNA Asp is an efficient substrate for Thermus thermophilus EF-Tu-GTP, suggesting that features other than the length of tRNA Sec prevent its recognition by EF-Tu-GTP. A stepwise mutational analysis of a minihelix derived from tRNA Sec in which sequence elements of tRNA Asp were introduced showed that the sequence of the amino acid- acceptor branch of Escherichia coli tRNA Sec contains a specific structural element that hinders its binding to T.thermophilus EF-Tu-GTP. This antideterminant is located in the 8th, 9th and 10th bp in the acceptor branch of tRNA Sec, corresponding to the last base pair in the amino acid acceptor stem and the two first pairs in the T-stem. The function of this C7.G66/G49.U65/C50.G64 box was tested by its transplantation into a minihelix derived from tRNA Asp, abolishing its recognition by EF-Tu-GTP. The specific role of this nucleotide combination is further supported by its absence in all known prokaryotic elongator tRNAs.     

Recognition mechanism of tRNA with tRNA(guanosine-2')methyltransferase from Thermus thermophilus HB 27

rRNA(Gm)methyltransferase from an extreme thermophile, Thermus thermophilus HB 27 specifically methylates the 2'-OH of the ribose ring of G18 in the invariant G18-G19 sequence in the D loop of tRNA. The interaction site on tRNA was presumed to be the D loop and stem structure. Destruction of tertiary structure of tRNA caused by heat resulted in a great decrease in the acceptor activity of methyl group. It was suggested by CD measurement that a conformational change of tRNA occurs when it forms an equimolar complex with Gm-methylase.     

Mapping contacts between Escherichia coli alanyl tRNA synthetase and 2' hydroxyls using a complete tRNA molecule

A dual-specific derivative of yeast tRNA(Phe) is described whose features facilitate structure-function studies of tRNAs. This tRNA has been made in three different bimolecular forms that allow modifications to be easily introduced into any position within the molecule. A set of deoxynucleotide substituted versions of this tRNA has been created and used to examine contacts between tRNA and Escherichia coli alanyl-tRNA synthetase, an enzyme previously shown to interact with 2'-hydroxyls in the acceptor stem of the tRNA. Because the present experiments used a full-length tRNA, several contacts were identified that had not been previously found using microhelix substrates. Contacts at similar sites in the T-loop are seen in the cocrystal structure of tRNA(Ser) and Thermus thermophilus seryl-tRNA synthetase.     

An intermediate step in the recognition of tRNA(Asp) by aspartyl-tRNA synthetase

The crystal structures of aspartyl-tRNA synthetase (AspRS) from Thermus thermophilus, a prokaryotic class IIb enzyme, complexed with tRNA(Asp) from either T. thermophilus or Escherichia coli reveal a potential intermediate of the recognition process. The tRNA is positioned on the enzyme such that it cannot be aminoacylated but adopts an overall conformation similar to that observed in active complexes. While the anticodon loop binds to the N-terminal domain of the enzyme in a manner similar to that of the related active complexes, its aminoacyl acceptor arm remains at the entrance of the active site, stabilized in its intermediate conformational state by non-specific interactions with the insertion and catalytic domains. The thermophilic nature of the enzyme, which manifests itself in a very low kinetic efficiency at 17 degrees C, the temperature at which the crystals were grown, is in agreement with the relative stability of this non-productive conformational state. Based on these data, a pathway for tRNA binding and recognition is proposed.     

Phenylalanyl-tRNA synthetase from Thermus thermophilus can attach two molecules of phenylalanine to tRNA(Phe).

Phenylalanyl-tRNA synthetase from the extreme thermophilic bacterium Thermus thermophilus can incorporate more than one molecule of phenylalanine into the tRNA(Phe). It is shown that the 'hyperaminoacylated' tRNA(Phe) is the bis-2',3'-O-phenylalanyl-tRNA(Phe), and its formation is typical for the thermophilic enzyme but does not occur for E. coli phenylalanyl-tRNA synthetase under the same conditions.     

tRNA discrimination by T. thermophilus phenylalanyl-tRNA synthetase at the binding step

The extent of tRNA recognition at the level of binding by Thermus thermophilus phenylalanyl-tRNA synthetase (PheRS), one of the most complex class II synthetases, has been studied by independent measurements of the enzyme association with wild-type and mutant tRNA(Phe)s as well as with non-cognate tRNAs. The data obtained, combined with kinetic data on aminoacylation, clearly show that PheRS exhibits more tRNA selectivity at the level of binding than at the level of catalysis. The anticodon nucleotides involved in base-specific interactions with the enzyme prevail both in the initial binding recognition and in favouring aminoacylation catalysis. Tertiary nucleotides of base pair G19-C56 and base triple U45-G10-C25 contribute primarily to stabilization of the correctly folded tRNA(Phe) structure, which is important for binding. Other nucleotides of the central core (U20, U16 and of the A26-G44 tertiary base pair) are involved in conformational adjustment of the tRNA upon its interaction with the enzyme. The specificity of nucleotide A73, mutation of which slightly reduces the catalytic rate of aminoacylation, is not displayed at the binding step. A few backbone-mediated contacts of PheRS with the acceptor and anticodon stems revealed in the crystal structure do not contribute to tRNA(Phe) discrimination, their role being limited to stabilization of the complex. The highest affinity of T. thermophilus PheRS for cognate tRNA, observed for synthetase-tRNA complexes, results in 100-3000-fold binding discrimination against non-cognate tRNAs.