Function of the Neurospora crassa mitochondrial tyrosyl-tRNA synthetase in RNA splicing. Role of the idiosyncratic N-terminal extension and different modes of interaction with different group I introns

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) promotes the splicing of group I introns by helping the intron RNA fold into the catalytically active structure. The regions required for splicing include an idiosyncratic N-terminal extension, the nucleotide-binding fold domain, and the C-terminal RNA-binding domain. Here, we show that the idiosyncratic N-terminal region is in fact comprised of two functionally distinct parts: an upstream region consisting predominantly of a predicted amphipathic alpha-helix (H0), which is absent from bacterial tyrosyl-tRNA synthetases (TyrRSs), and a downstream region, which contains predicted alpha-helices H1 and H2, corresponding to features in the X-ray crystal structure of the Bacillus stearothermophilus TyrRS. Bacterial genetic assays with libraries of CYT-18 mutants having random mutations in the N-terminal region identified functionally important amino acid residues and supported the predicted structures of the H0 and H1 alpha-helices. The function of N and C-terminal domains of CYT-18 was investigated by detailed biochemical analysis of deletion mutants. The results confirmed that the N-terminal extension is required only for splicing activity, but surprisingly, at least in the case of the N. crassa mitochondrial (mt) large ribosomal subunit (LSU) intron, it appears to act primarily by stabilizing the structure of another region that interacts directly with the intron RNA. The H1/H2 region is required for splicing activity and TyrRS activity with the N. crassa mt tRNA(Tyr), but not for TyrRS activity with Escherichia coli tRNA(Tyr), implying a somewhat different mode of recognition of the two tyrosyl-tRNAs. Finally, a CYT-18 mutant lacking the N-terminal H0 region is totally defective in binding or splicing the N. crassa ND1 intron, but retains substantial residual activity with the mt LSU intron, and conversely, a CYT-18 mutant lacking the C-terminal RNA-binding domain is totally defective in binding or splicing the mt LSU intron, but retains substantial residual activity with the ND1 intron. These findings lead to the surprising conclusion that CYT-18 promotes splicing via different sets of interactions with different group I introns. We suggest that these different modes of promoting splicing evolved from an initial interaction based on the recognition of conserved tRNA-like structural features of the group I intron catalytic core.

Conserved amino acids near the carboxy terminus of bacterial tyrosyl-tRNA synthetase are involved in tRNA and Tyr-AMP binding

Bacterial tyrosyl-tRNA synthetases occur in two large subfamilies, TyrRS and TyrRZ, that possess about 25% amino acid identity. Their amino-terminal region, the active site domain, is more conserved (>36% identity). The carboxy-terminal segment of these enzymes includes the tRNA binding domain and contains only few conserved residues. Replacement of three of these residues in Acidithiobacillus ferrooxidans TyrRZ revealed that S356 and K395 play roles in tRNA binding, while H306, a residue at the junction of the catalytic and tRNA binding domains, stabilizes the Tyr-AMP:TyrRZ complex. The replacement data suggest that conserved amino acids in A. ferrooxidans TyrRZ and Bacillus stearothermophilus TyrRS play equivalent roles in enzyme function.

Major tyrosine identity determinants in Methanococcus jannaschii and Saccharomyces cerevisiae tRNA(Tyr) are conserved but expressed differently

Using in vitro tRNA transcripts and minihelices it was shown that the tyrosine identity for tRNA charging by tyrosyl-tRNA synthetase (TyrRS) from the archaeon Methanococcus jannaschii is determined by six nucleotides: the discriminator base A73 and the first base-pair C1-G72 in the acceptor stem together with the anticodon triplet. The anticodon residues however, participate only weakly in identity determination, especially residues 35 and 36. The completeness of the aforementioned identity set was verified by its tranfer into several tRNAs which then become as efficiently tyrosylatable as the wild-type transcript from M. jannaschii. Temperature dependence experiments on both the structure and the tyrosylation properties of M. jannaschii and yeast tRNA(Tyr) transcripts show that the archaeal transcript has greater structural stability and enhanced aminoacylation behaviour than the yeast transcript. Tyrosine identity in M. jannaschii is compared to that in yeast, and the conservation of the major determinant in both organisms, namely the C1-G72 pair, gives additional support to the existence of a functional connection between archaeal and eukaryotic aminoacylation systems.

Protein-protein interaction between Bacillus stearothermophilus tyrosyl-tRNA synthetase subdomains revealed by a bacterial two-hybrid system

We have recently developed a bacterial two-hybrid system (BACTH), based on functional complementation between two fragments of the catalytic domain of Bordetella pertussis adenylate cyclase (AC), that allows an easy in vivo screening and selection of functional interactions between two proteins in Escherichia coli. In this work, we have further explored the potentialities of the BACTH system to study protein-protein interactions, using as a model, the interactions between various subdomains of the dimeric tyrosyl-tRNA synthetase (TyrRS) of Bacillus stearothermophilus. Using the BACTH system we confirmed the known interactions of the alpha/beta domains and those between the alpha/beta domain and the alpha domain that could be anticipated from the three-dimensional structure of TyrRS. Interestingly, the BACTH system revealed the unexpected interaction between the TyrRS alpha domains which is presumably mediated by a pseudo-leucine zipper motif. This study illustrates the interest of the bacterial two-hybrid system to delineate interacting domains of proteins and shows that it can reveal interactions that occur in vivo and that were not anticipated from the three-dimensional structure of the protein of interest.

A mutant Escherichia coli tyrosyl-tRNA synthetase utilizes the unnatural amino acid azatyrosine more efficiently than tyrosine

Alloproteins, proteins that contain unnatural amino acids, have immense potential in biotechnology and medicine. Although various approaches for alloprotein production exist, there is no satisfactory method to produce large quantities of alloproteins containing unnatural amino acids in specific positions. The tyrosine analogue azatyrosine, l-beta-(5-hydroxy-2-pyridyl)-alanine, can convert the ras-transformed phenotype to normal phenotype, presumably by its incorporation into cellular proteins. This provided the stimulus for isolation of a mutant tyrosyl-tRNA synthetase (TyrRS) capable of charging azatyrosine to tRNA. A plasmid library of randomly mutated Escherichia coli tyrS (encoding TyrRS) was made by polymerase chain reaction techniques. The desired TyrRS mutants were selected by screening for in vivo azatyrosine incorporation of E. coli cells transformed with the mutant tyrS plasmids. One of the clones thus isolated, R-6-A-7, showed a 17-fold higher in vivo activity for azatyrosine incorporation than wild-type TyrRS. The mutant tyrS gene contained a single point mutation resulting in replacement of phenylalanine by serine at position 130 in the protein. Structural modeling revealed that position 130 is located close to Asp(182), which directly interacts with tyrosyladenylate. Kinetic analysis of aminoacyl-tRNA formation by the wild-type and mutated F130S TyrRS enzymes showed that the specificity for azatyrosine, measured by the ratios of k(cat)/K(m) for tyrosine and the analogue, increased from 17 to 36 as a result of the F130S mutation. Thus, the high discrimination against azatyrosine is significantly reduced in the mutant enzyme. These results suggest that utilization of F130S TyrRS for in vivo protein biosynthesis may lead to efficient production of azatyrosine-containing alloproteins.

Stabilization of the transition state for the transfer of tyrosine to tRNA(Tyr) by tyrosyl-tRNA synthetase

Aminoacylation of tRNA(Tyr) involves two steps: (1) tyrosine activation to form the tyrosyl-adenylate intermediate; and (2) transfer of tyrosine from the tyrosyl-adenylate intermediate to tRNA(Tyr). In Bacillus stearothermophilus tyrosyl-tRNA synthetase, Asp78, Tyr169, and Gln173 have been shown to form hydrogen bonds with the alpha-ammonium group of the tyrosine substrate during the first step of the aminoacylation reaction. Asp194 and Gln195 stabilize the transition state complex for the first step of the reaction by hydrogen bonding with the 2'-hydroxyl group of AMP and the carboxylate oxygen atom of tyrosine, respectively. Here, the roles that Asp78, Tyr169, Gln173, Asp194, and Gln195 play in catalysis of the second step of the reaction are investigated. Pre-steady-state kinetic analyses of alanine variants at each of these positions shows that while the replacement of Gln173 by alanine does not affect the initial binding of the tRNA(Tyr) substrate, it destabilizes the transition state complex for the second step of the reaction by 2.3 kcal/mol. None of the other alanine substitutions affects either the initial binding of the tRNA(Tyr) substrate or the stability of the transition state for the second step of the aminoacylation reaction. Taken together, the results presented here and the accompanying paper are consistent with a concerted reaction mechanism for the transfer of tyrosine to tRNA(Tyr), and suggest that catalysis of the second step of tRNA(Tyr) aminoacylation involves stabilization of a transition state in which the scissile acylphosphate bond of the tyrosyl-adenylate species is strained. Cleavage of the scissile bond on the breakdown of the transition state alleviates this strain.

Correlating amino acid conservation with function in tyrosyl-tRNA synthetase

Sequence comparisons have been combined with mutational and kinetic analyses to elucidate how the catalytic mechanism of Bacillus stearothermophilus tyrosyl-tRNA synthetase evolved. Catalysis of tRNA(Tyr) aminoacylation by tyrosyl-tRNA synthetase involves two steps: activation of the tyrosine substrate by ATP to form an enzyme-bound tyrosyl-adenylate intermediate, and transfer of tyrosine from the tyrosyl-adenylate intermediate to tRNA(Tyr). Previous investigations indicate that the class I conserved KMSKS motif is involved in only the first step of the reaction (i.e. tyrosine activation). Here, we demonstrate that the class I conserved HIGH motif also is involved only in the tyrosine activation step. In contrast, one amino acid that is conserved in a subset of the class I aminoacyl-tRNA synthetases, Thr40, and two amino acids that are present only in tyrosyl-tRNA synthetases, Lys82 and Arg86, stabilize the transition states for both steps of the tRNA aminoacylation reaction. These results imply that stabilization of the transition state for the first step of the reaction by the class I aminoacyl-tRNA synthetases preceded stabilization of the transition state for the second step of the reaction. This is consistent with the hypothesis that the ability of aminoacyl-tRNA synthetases to catalyze the activation of amino acids with ATP preceded their ability to catalyze attachment of the amino acid to the 3' end of tRNA. We propose that the primordial aminoacyl-tRNA synthetases replaced a ribozyme whose function was to promote the reaction of amino acids and other small molecules with ATP.

Function of tyrosyl-tRNA synthetase in splicing group I introns: an induced-fit model for binding to the P4-P6 domain based on analysis of mutations at the junction of the P4-P6 stacked helices

We used an Escherichia coli genetic assay based on the phage T4 td intron to test the ability of the Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) to suppress mutations that cause structural defects around its binding site in the P4-P6 domain of the group I intron catalytic core. We analyzed all possible combinations of nucleotides at either P4 bp-1 or P6 bp-1, which together form the junction of the P4-P6 stacked helices, and looked for synergistic effects in double mutants. Most mutations at either position inhibit self-splicing, but can be suppressed by CYT-18. CYT-18 can compensate efficiently for mutations that disrupt base-pairing at either P4 bp-1 or P6 bp-1, for mutations at P6 bp-1 that disrupt the base-triple interaction with J3/4-3, and for nucleotide substitutions at either position that are predicted to be suboptimal for base stacking, based on the analysis of DNA four-way junctions. However, CYT-18 has difficulty suppressing combinations of mutations at P4 bp-1 and P6 bp-1 that simultaneously disrupt base-pairing and base stacking. Thermal denaturation and Fe(II)-EDTA analysis showed that mutations at the junction of the P4-P6 stacked helices lead to grossly impaired tertiary-structure formation centered in the P4-P6 domain. CYT-18-suppressible mutants bind the protein with K(d) values up to 79-fold higher than that for the wild-type intron, but in all cases tested, the k(off) value for the complex remains within twofold of the wild-type value, suggesting that the binding site can be formed properly and that the increased K(d) value reflects primarily an increased k(on) value for the binding of CYT-18 to the misfolded intron. Our results indicate that the P4/P6 junction is a linchpin region, where even small nucleotide substitutions grossly disrupt the catalytically-active group I intron tertiary structure, and that CYT-18 binding induces the formation of the correct structure in this region, leading to folding of the group I intron catalytic core.

Azatyrosine. Mechanism of action for conversion of transformed phenotype to normal

Azatyrosine [L-beta-(5-hydroxy-2-pyridyl)-alanine] has the unique property of converting ras- or c-erbB-2 transformed phenotype to normal. The administration of azatyrosine also inhibits tumor formation in transgenic mice harboring the normal human c-Ha-ras which is mutated during treatment with various chemical carcinogens. To elucidate the molecular mechanism, we investigated how azatyrosine functions and what are its major targets. Azatyrosine functions downstream of ras; azatyrosine does not alter either the level of GTP-bound Ras or the total amount of Ras. Instead, azatyrosine inhibits the activation of c-Raf-1 kinase by oncogenic c-ErbB-2, resulting in inactivation of AP1. It is interesting that azatyrosine also restores the expression of the rhoB gene, the product of which regulates the formation of actin stress fibers. Azatyrosine is incorporated into cellular proteins to replace tyrosine. Several experiments indicate that replacement of tyrosine is likely to be a cause for its conversion of transformed phenotype to normal. To prove this hypothesis, we are attempting to develop a mutant of tyrosyl-tRNA synthetase that, unlike wild type, can aminoacylate azatyrosine more efficiently than can tyrosine.

The anticodon-binding domain of tyrosyl-tRNA synthetase: state of folding and origin of the crystallographic disorder

The C-terminal domain (residues 320-419) of tyrosyl-tRNA synthetase (TyrRS) from Bacillus stearothermophilus is disordered in the crystal structure. Its function consists of binding the anticodon of tRNA(Tyr). We undertook to characterize its conformational state. A hybrid between the C-terminal fragment and a His-tag sequence was constructed and purified in large amounts. Analyses by mass spectrometry and analytical ultracentrifugation showed that the C-terminal fragment, thus purified, was not degraded and that it neither dimerized nor aggregated. Its far- and near-UV circular dichroism spectra revealed a high content in secondary structures and an asymmetrical environment of its aromatic residues. Each spectrum could be reconstructed by the difference between the corresponding spectra for the full-length TyrRS and for its N-terminal fragment. The Stokes radius of the C-terminal fragment, measured by size exclusion chromatography, indicated a condensed globular state. The fluorescence of ANS (a small hydrophobic probe) showed that the surface of the C-terminal fragment was more hydrophilic than that of a molten globule. These results on the C-terminal fragment and our previous observations that it can undergo cooperative transitions, demonstrated the following points: it is not in a disordered or molten globular state, it has a defined and stable three-dimensional structure, its structures are similar in its isolated and integrated forms, and the apparent disorder in the crystals of the full-length synthetase must be due to the flexibility of the polypeptide segment that links the N- and C-terminal domains. Thus, TyrRS has not evolved strong noncovalent interactions between its catalytic and anticodon-binding domains, contrary to the other synthetases.

Major anticodon-binding region missing from an archaebacterial tRNA synthetase

The small size of the archaebacterial Methanococcus jannaschii tyrosyl-tRNA synthetase may give insights into the historical development of tRNAs and tRNA synthetases. The L-shaped tRNA has two major arms-the acceptor.TpsiC minihelix with the amino acid attachment site and the anticodon-containing arm. The structural organization of the tRNA synthetases parallels that of tRNAs. The more ancient synthetase domain contains the active site and insertions that interact with the minihelix portion of the tRNA. A second, presumably more recent, domain interacts with the anticodon-containing section of tRNA. The small size of the M. jannaschii enzyme is due to the absence of most of the second domain, including a segment thought to bind to the anticodon. Consistent with the absence of an anticodon-binding motif, a mutation of the central base of the anticodon had a relatively small effect on the aminoacylation efficiency of the M. jannaschii enzyme. In contrast, others showed earlier that the same mutation severely reduced charging by a normal-sized bacterial enzyme that has the aforementioned anticodon-binding motif. However, the M. jannaschii enzyme has a peptide insertion into its catalytic domain. This insertion is shared with all other tyrosyl-tRNA synthetases and is needed for a critical minihelix interaction. We show that the M. jannaschii enzyme is active on minihelix substrates over a wide temperature range and has preserved the same peptide-dependent minihelix specificity seen in other tyrosine enzymes. These findings are consistent with the concept that anticodon interactions of tRNA synthetases were later adaptations to the emerging synthetase-tRNA complex that was originally framed around the minihelix.

Domain-domain communication in a miniature archaebacterial tRNA synthetase

The three-dimensional structure of tRNA is organized into two domains-the acceptor-TPsiC minihelix with the amino acid attachment site and a second, anticodon-containing, stem-loop domain. Aminoacyl-tRNA synthetases have a structural organization that roughly recapitulates the two-domain organization of tRNAs-an older primary domain that contains the catalytic center and interacts with the minihelix and a secondary, more recent, domain that makes contacts with the anticodon-containing arm. The latter contacts typically are essential for enhancement of the catalytic constant k(cat) through domain-domain communication. Methanococcus jannaschii tyrosyl-tRNA synthetase is a miniature synthetase with a tiny secondary domain suggestive of an early synthetase evolving from a one-domain to a two-domain structure. Here we demonstrate functional interactions with the anticodon-containing arm of tRNA that involve the miniaturized secondary domain. These interactions appear not to include direct contacts with the anticodon triplet but nonetheless lead to domain-domain communication. Thus, interdomain communication may have been established early in the evolution from one-domain to two-domain structures.

Molecular recognition of tyrosinyl adenylate analogues by prokaryotic tyrosyl tRNA synthetases

Molecular modelling and synthetic studies have been carried out on tyrosinyl adenylate and analogues to probe the interactions seen in the active site of the X-ray crystal structure of tyrosyl tRNA synthetase from Bacillus stearothermophilus, and to search for new inhibitors of this enzyme. Micromolar and sub-micromolar inhibitors of tyrosyl tRNA synthetases from both B. stearothermophilus and Staphylococcus aureus have been synthesised. The importance of the adenine ring to the binding of tyrosinyl adenylate to the enzyme, and the importance of water-mediated hydrogen bonding interactions, have been highlighted. The inhibition data has been further supported by homology modelling with the S. aureus enzyme, and by ligand docking studies.

Effects of growth conditions on expression of mycobacterial murA and tyrS genes and contributions of their transcripts to precursor rRNA synthesis

All mycobacteria studied to date have an rRNA operon, designated rrnA, located downstream from a single copy of the murA gene, which encodes an enzyme (EC 2.5.1.7) important for peptidoglycan synthesis. The rrnA operon has a promoter, P1(A), located within the coding region of murA, near the 3' end. Samples of RNA were isolated from Mycobacterium tuberculosis at different stages of the growth cycle and from Mycobacterium smegmatis grown under different conditions. RNase protection assays were used to investigate transcripts of both murA and rrnA. Transcription of murA was found to continue into the 16S rRNA gene, as if murA and rrnA form a hybrid (protein coding-rRNA coding) operon. During the growth of M. tuberculosis, the hybrid operon contributed approximately 2% to total pre-rRNA. Analysis of M. smegmatis RNA revealed that the level of murA RNA depended on the growth rate and that the patterns of expression during the growth cycle were different for murA and rrnA. M. smegmatis has a second rRNA operon, rrnB, located downstream from a single copy of the tyrS gene, encoding tyrosyl-tRNA synthetase. Transcription of tyrS was found to continue into the 16S rRNA gene rrnB. The hybrid tyrS-rrnB operon contributed 0.2 to 0.6% to rrnB transcripts. The pattern of tyrS expression during the growth cycle matched the pattern of rrnB expression, reflecting the essential role of TyrS and rRNA in protein biosynthesis.

Co-expression of yeast amber suppressor tRNATyr and tyrosyl-tRNA synthetase in Escherichia coli: possibility to expand the genetic code

An efficient system was developed for the co-expression of a yeast tRNATyr/tyrosyl-tRNA synthetase (TyrRS) pair in Escherichia coli. Analysis of suppression patterns using several sets of E. coli and lambda phage mutants indicated that the expressed yeast suppressor tRNATyr was aminoacylated only with tyrosine by its cognate yeast TyrRS and not by E. coli TyrRS or other aminoacyl-tRNA synthetases. This extra tRNA/TyrRS pair is expected to be a key bridgehead for developing an in vivo system for the site-directed incorporation of unnatural amino acids into proteins.

Evolution of genes, evolution of species: the case of aminoacyl-tRNA synthetases

All of the aminoacyl-tRNA synthetase (aaRS) sequences currently available in the data banks have been subjected to a systematic analysis aimed at finding gene duplications, genetic recombinations, and horizontal transfers. Evidence is provided for the occurrence (or probable occurrence) of such phenomena within this class of enzymes. In particular, it is suggested that the monomeric PheRS from the yeast mitochondrion is a chimera of the alpha and beta chains of the standard tetrameric protein. In addition, it is proposed that the dimeric and tetrameric forms of GlyRS are the result of a double and independent acquisition of the same specificity within two different subclasses of aaRS. The phylogenetic reconstructions of the evolutionary histories of the genes encoding aaRS are shown to be extremely diverse. While large segments of the population are consistent with the broad grouping into the three Woesian domains, some phylogenetic reconstructions do not place the Archae and the Eucarya as sister groups but, rather, show a gram-negative bacteria/eukaryote clustering. In addition, many individual genes pose difficulties that preclude any simple evolutionary scheme. Thus, aaRS's are clearly a paradigm of F. Jacob's "odd jobs of evolution" but, on the whole, do not call into question the evolutionary scenario originally proposed by Woese and subsequently refined by others.

Analysis of cis-acting sequence and structural elements required for antitermination of the Bacillus subtilis tyrS gene

The Bacillus subtilis tyrS gene belongs to the T box family of aminoacyl-tRNA synthetase and amino acid biosynthesis genes, which are regulated by a common mechanism of transcriptional antitermination. Each gene is induced by specific amino acid limitation; the uncharged cognate tRNA is the effector inducing transcription of the full-length message. The leader regions of the genes in this family share a number of conserved primary sequence and secondary structural elements, the functions of which are unknown. In this study, we examine these regions and report the effects of mutations in several of these elements. In addition, two alternative basepairings in the F box region were found to be necessary for tyrS antitermination.

Evidence for the early divergence of tryptophanyl- and tyrosyl-tRNA synthetases

Each amino acid is attached to its cognate tRNA by a distinct aminoacyl-tRNA synthetase (aaRS). The conventional evolutionary view is that the modern complement of synthetases existed prior to the divergence of eubacteria and eukaryotes. Thus comparisons of prokaryotic and eukaryotic aminoacyl-tRNA synthetases of the same type (charging specificity) should show greater sequence similarities than comparisons between synthetases of different types-and this is almost always so. However, a recent study [Ribas de Pouplana L, Furgier M, Quinn CL, Schimmel P (1996) Proc Natl Acad Sci USA 93:166-170] suggested that tryptophanyl- (TrpRS) and tyrosyl-tRNA (TyrRS) synthetases of the Eucarya (eukaryotes) are more similar to each other than either is to counterparts in the Bacteria (eubacteria). Here, we reexamine the evolutionary relationships of TyrRS and TrpRS using a broader range of taxa, including new sequence data from the Archaea (archaebacteria) as well as species of Eucarya and Bacteria. Our results differ from those of Ribas de Pouplana et al.: All phylogenetic methods support the separate monophyly of TrpRS and TyrRS. We attribute this result to the inclusion of the archaeal data which might serve to reduce long branch effects possibly associated with eukaryotic TrpRS and TyrRS sequences. Furthermore, reciprocally rooted phylogenies of TrpRS and TyrRS sequences confirm the closer evolutionary relationship of Archaea to eukaryotes by placing the root of the universal tree in the Bacteria.

Species-specific tRNA recognition in relation to tRNA synthetase contact residues

In spite of variations in the sequences of tRNAs, the genetic code (anticodon trinucleotides) is conserved in evolution. However, non-anticodon nucleotides which are species specific are known to prevent a given tRNA from functioning in all organisms. Conversely, species-specific tRNA contact residues in synthetases should also prevent cross-species acylation in a predictable way. To address this question, we investigated the relatively small tyrosine tRNA synthetase where contacts of Escherichia coli tRNA(Tyr) with the alpha2 dimeric protein have been localized by others to four specific sequence clusters on the three-dimensional structure of the Bacillus stearothermophilus enzyme. We used specific functional tests with a previously not-sequenced and not-characterized Mycobacterium tuberculosis enzyme and showed that it demonstrates species-specific aminoacylation in vivo and in vitro. The specificity observed fits exactly with the presence of the clusters characteristic of those established as important for recognition of E. coli tRNA. Conversely, we noted that a recent analysis of the tyrosine enzyme from the eukaryote pathogen Pneumocystis carinii showed just the opposite species specificity of tRNA recognition. According to our alignments, the sequences of the clusters diverge substantially from those seen with the M. tuberculosis, B. stearothermophilus and other enzymes. Thus, the presence or absence of species-specific residues in tRNA synthetases correlates in both directions with cross-species aminoacylation phenotypes, without reference to the associated tRNA sequences. We suggest that this kind of analysis can identify those synthetase-tRNA covariations which are needed to preserve the genetic code. These co-variations might be exploited to develop novel antibiotics against pathogens such as M. tuberculosis and P. carinii.

Specificity of tRNA-mRNA interactions in Bacillus subtilis tyrS antitermination

The Bacillus subtilis tyrS gene, encoding tyrosyl-tRNA synthetase, is a member of the T-box family of genes, which are regulated by control of readthrough of a leader region transcriptional terminator. Readthrough is induced by interaction of the cognate uncharged tRNA with the leader; the system responds to decreased tRNA charging, caused by amino acid limitation or insufficient levels of the aminoacyl-tRNA synthetase. Recognition of the cognate tRNA is mediated by pairing of the anticodon of the tRNA with the specifier sequence of the leader, a codon specifying the appropriate amino acid; a second interaction between the acceptor end of the tRNA and an antiterminator structure is also important. Certain switches of the specifier sequence to a new codon result in a switch in the specificity of the amino acid response, while other switches do not. These effects may reflect additional sequence or structural requirements for the mRNA-tRNA interaction. This study includes investigation of the effects of a large number of specifier sequence switches in tyrS and analysis of structural differences between tRNA(Tyr) and tRNA species which interact inefficiently with the tyrS leader to promote antitermination.

Characterization of Neurospora mitochondrial group I introns reveals different CYT-18 dependent and independent splicing strategies and an alternative 3' splice site for an intron ORF

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) functions in splicing the N. crassa mitochondrial large rRNA intron by stabilizing the catalytically active structure of the intron core. Here, a comprehensive study of N. crassa mtDNA group I introns identified two additional introns, cob-I2 and the ND1 intron, that are dependent on CYT-18 for splicing in vitro and in vivo. The other seven N. crassa mtDNA group I introns are not CYT-18-dependent and include five that self-splice and two that do not splice under any conditions examined. Some of these introns may require maturases or other proteins for efficient splicing. All but one of the non-CYT-18-dependent introns contain large peripheral extensions of the P5 stem, related to the P5abc structure that blocks CYT-18 binding to the Tetrahymena large rRNA intron. The remaining non-CYT-18-dependent intron, cob-I1, contains a long, peripheral extension of the P9 stem, denoted P9.1, which also impedes CYT-18 binding. Detailed analysis of the CYT-18-dependent ND1 intron showed that two 3' splice sites are used in vitro and in vivo. The proximal, alternative 3' splice site brings the intron open reading frame, which potentially encodes a mobility endonuclease, in frame with the upstream exon, possibly providing a means of expression. Considered together, our results show that group I introns in N. crassa mitochondria use a variety of strategies involving different proteins and/or RNA structures to assist splicing, and they support the hypothesis that CYT-18 and the peripheral RNA structure P5abc are alternative evolutionary adaptations for stabilizing the active structure of the intron core.

A tyrosyl-tRNA synthetase recognizes a conserved tRNA-like structural motif in the group I intron catalytic core

The Neurospora crassa mitochondrial (mt) tyrosyl-tRNA synthetase (CYT-18 protein) functions in splicing group I introns, in addition to aminoacylating tRNA(Tyr). Here, we compared the CYT-18 binding sites in the N. crassa mt LSU and ND1 introns with that in N. crassa mt tRNA(Tyr) by constructing three-dimensional models based on chemical modification and RNA footprinting data. Remarkably, superimposition of the CYT-18 binding sites in the model structures revealed an extended three-dimensional overlap between the tRNA and the group I intron catalytic core. Our results provide insight into how an RNA-splicing factor can evolve from a cellular RNA-binding protein. Further, the structural similarities between group I introns and tRNAs are consistent with an evolutionary relationship and suggest a general mechanism for the evolution of complex catalytic RNAs.

Efficient synthesis of a 72-kDa mitochondrial polypeptide using the yeast Ty expression system

Using the Ty system from yeast we report the efficient expression of a heterologous eukaryotic gene encoding a 72 kDa mitochondrial polypeptide. The pFM2IIBgIII expression vector was initially modified for this purpose by inserting the factor X(a) protease cleavage site. The TyA gene, which encodes the structural component of the yeast virus-like particles (VLPs), and the eukaryotic yst1 gene, encoding a 72 kDa mitochondrial tyrosyl-tRNA synthetase from the filamentous fungus Podospora anserina, were subsequently fused to the factor X(a) cleavage site. The resulting chimeric gene, in which the two polypeptide coding sequences are separated by the factor X(a) cleavage site, was expressed in yeast. High yield expression of this foreign protein, which was isolated from yeast transformants as hybrid TyVLPs, was verified after factor X(a) treatment by SDS polyacrylamide gel electrophoresis and antibody detection. The strategy presented here should be useful for expressing a wide variety of eukaryotic genes.

Disordered C-terminal domain of tyrosyl transfer-RNA synthetase: evidence for a folded state

The C-terminal domain (residues 320 to 419) of tyrosyl-tRNA synthetase from Bacillus stearothermophilus (Bst-TyrRS) is necessary for the binding of tRNA(Tyr) but disordered in the crystal structure. Four different criteria showed that the isolated C-terminal domain of Bst-TyrRS was at least partially folded in solution. Its spectrum of circular dichroism was compatible with a high content of secondary structure elements (56% of its residues) and these structural elements disappeared in 7.5 M urea. It was unfolded by urea along a unique transition, around 6.0 M, according to the variations in the fluorescence of its tyrosine residues and in its electrophoretic mobility through transverse gradient gels. It was denatured by heat with a temperature of half-precipitation in 30 minutes that was equal to 67.9 degrees C and close to the Bst-TyrRS one, 68.7 degrees C. Its transitions of denaturation by urea or temperature were weakly cooperative. The C-terminal domains of the TyrRSs from Escherichia coli (Eco-TyrRS) and B. stearothermophilus could be genetically exchanged without a significant loss of aminoacylation activity. A hybrid between the N-terminal domain of Bst-TyrRS and the C-terminal domain of Eco-TyrRS was precipitated by heat in 30 minutes following two transitions: 83% of the molecules were precipitated with a temperature of half-transition (51.6 degrees C) close to the Eco-TyrRS one (48.6 degrees C). The remainder was precipitated with a temperature of half-transition (65.5 degrees C) close to the Bst-TyrRS one (67.2 degrees C) or that of its N-terminal domain (68.0 degrees C). These results showed that the C-terminal domain of Eco-TyrRS could undergo a transition from a soluble active conformation to an insoluble one. The denaturations of Bst-TyrRS and of its N-terminal domain by urea occurred with two successive transitions, around 4 M and 6 M, and thus according to a complex mechanism.