Solution structure of a tRNA with a large variable region: yeast tRNASer

Phylogenomics and plastomics offer new evolutionary perspectives on Kalanchoideae (Crassulaceae)

BACKGROUND AND AIMS

Kalanchoideae is one of three subfamilies within Crassulaceae and contains four genera. Despite previous efforts, the phylogeny of Kalanchoideae remains inadequately resolved with persistent issues including low support, unstructured topologies and polytomies. This study aimed to address two central objectives: (1) resolving the pending phylogenetic questions within Kalanchoideae by using organelle-scale 'barcodes' (plastomes) and nuclear data; and (2) investigating interspecific diversity patterns among Kalanchoideae plastomes.

METHODS

To explore the plastome evolution in Kalanchoideae, we newly sequenced 38 plastomes representing all four constituent genera (Adromischus, Cotyledon, Kalanchoe and Tylecodon). We performed comparative analyses of plastomic features, including GC and gene contents, gene distributions at the IR (inverted repeat) boundaries, nucleotide divergence, plastomic tRNA (pttRNA) structures and codon aversions. Additionally, phylogenetic inferences were inferred using both the plastomic dataset (79 genes) and nuclear dataset (1054 genes).

KEY RESULTS

Significant heterogeneities were observed in plastome lengths among Kalanchoideae, strongly correlated with LSC (large single copy) lengths. Informative diversities existed in the gene content at SSC/IRa (small single copy/inverted repeat a), with unique patterns individually identified in Adromischus leucophyllus and one major Kalanchoe clade. The ycf1 gene was assessed as a shared hypervariable region among all four genera, containing nine lineage-specific indels. Three pttRNAs exhibited unique structures specific to Kalanchoideae and the genera Adromischus and Kalanchoe. Moreover, 24 coding sequences revealed a total of 41 lineage-specific unused codons across all four constituent genera. The phyloplastomic inferences clearly depicted internal branching patterns in Kalanchoideae. Most notably, by both plastid- and nuclear-based phylogenies, our research offers the first evidence that Kalanchoe section Eukalanchoe is not monophyletic.

CONCLUSIONS

This study conducted comprehensive analyses on 38 newly reported Kalanchoideae plastomes. Importantly, our results not only reconstructed well-resolved phylogenies within Kalanchoideae, but also identified highly informative unique markers at the subfamily, genus and species levels. These findings significantly enhance our understanding of the evolutionary history of Kalanchoideae.

Structural Diversities and Phylogenetic Signals in Plastomes of the Early-Divergent Angiosperms: A Case Study in Saxifragales

As representative of the early-divergent groups of angiosperms, Saxifragales is extremely divergent in morphology, comprising 15 families. Within this order, our previous case studies observed significant structural diversities among the plastomes of several lineages, suggesting a possible role in elucidating their deep phylogenetic relationships. Here, we collected 208 available plastomes from 11 constituent families to explore the evolutionary patterns among Saxifragales. With thorough comparisons, the losses of two genes and three introns were found in several groups. Notably, 432 indel events have been observed from the introns of all 17 plastomic intron-containing genes, which could well play an important role in family barcoding. Moreover, numerous heterogeneities and strong intrafamilial phylogenetic implications were revealed in pttRNA (plastomic tRNA) structures, and the unique structural patterns were also determined for five families. Most importantly, based on the well-supported phylogenetic trees, evident phylogenetic signals were detected in combinations with the identified pttRNAs features and intron indels, demonstrating abundant lineage-specific characteristics for Saxifragales. Collectively, the results reported here could not only provide a deeper understanding into the evolutionary patterns of Saxifragales, but also provide a case study for exploring the plastome evolution at a high taxonomic level of angiosperms.

Plastomes of Bletilla (Orchidaceae) and Phylogenetic Implications

The genus Bletilla is a small genus of only five species distributed across Asia, including B. chartacea, B. foliosa, B. formosana, B. ochracea and B. striata, which is of great medicinal importance. Furthermore, this genus is a member of the key tribe Arethuseae (Orchidaceae), harboring an extremely complicated taxonomic history. Recently, the monophyletic status of Bletilla has been challenged, and the phylogenetic relationships within this genus are still unclear. The plastome, which is rich in both sequence and structural variation, has emerged as a powerful tool for understanding plant evolution. Along with four new plastomes, this work is committed to exploring plastomic markers to elucidate the phylogeny of Bletilla. Our results reveal considerable plastomic differences between B. sinensis and the other three taxa in many aspects. Most importantly, the specific features of the IR junction patterns, novel pttRNA structures and codon aversion motifs can serve as useful molecular markers for Bletilla phylogeny. Moreover, based on maximum likelihood and Bayesian inference methods, our phylogenetic analyses based on two datasets of Arethuseae strongly imply that Bletilla is non-monophyletic. Accordingly, our findings from this study provide novel potential markers for species identification, and shed light on the evolution of Bletilla and Arethuseae.

Plastome evolution of Aeonium and Monanthes (Crassulaceae): insights into the variation of plastomic tRNAs, and the patterns of codon usage and aversion

This study reported 13 new plastomes from Aeonium and Monanthes, and observed new markers for phylogeny and DNA barcoding, such as novel tRNA structures and codon usage bias and aversion. The Macaronesian clade of Crassulaceae consists of three genera: Aichryson, with about 15 species; Monanthes, with about 10 species; Aeonium, with about 40 species. Within this clade, Aeonium, known as "the botanical equivalent of Darwin's finches", is regarded as an excellent model plant for researching adaptive evolution. Differing from the well-resolved relationships among three genera of the Macaronesian clade, the internal branching patterns within the genus Aeonium are largely unclear. In this study, we first reported 13 new plastomes from genus Aeonium and the closely related genus Monanthes. We further performed comprehensive analyses of the plastomes, with focuses on the secondary structures of pttRNAs and the patterns of codon usage and aversion. With a typical circular and quadripartite structure, the 13 plastomes ranged from 149,900 to 151,030 bp in size, and the unique pattern in IR junctions might become a family-specific marker for Crassulaceae species. Surprisingly, the π values of plastomes from Monanthes were almost twice those from Aeonium. Most importantly, we strongly recommend that highly polymorphic regions, novel putative pttRNA structures, patterns of codon usage bias and aversion derived from plastomes might have phylogenetic implications, and could act as new markers for DNA barcoding of plants. The results of phylogenetic analyses strongly supported a clear internal branching pattern in Macaronesian clade (represented by Aeonium and Monanthes), with higher nodal support values. The findings reported here will provide new insights into the variation of pttRNAs, and the patterns of codon usage and aversion of the family Crassulaceae.

Site-Specific Synthesis of N4-Acetylcytidine in RNA Reveals Physiological Duplex Stabilization

N⁴-Acetylcytidine (ac4C) is a post-transcriptional modification of RNA that is conserved across all domains of life. All characterized sites of ac4C in eukaryotic RNA occur in the central nucleotide of a 5'-CCG-3' consensus sequence. However, the thermodynamic consequences of cytidine acetylation in this context have never been assessed due to its challenging synthesis. Here, we report the synthesis and biophysical characterization of ac4C in its endogenous eukaryotic sequence context. First, we develop a synthetic route to homogeneous RNAs containing electrophilic acetyl groups. Next, we use thermal denaturation to interrogate the biochemical effects of ac4C on duplex stability and mismatch discrimination in a native sequence found in human rRNA. Finally, we demonstrate the ability of this chemistry to incorporate ac4C into the complex modification landscape of human tRNA and use duplex melting to highlight an enforcing role for ac4C in this unique sequence context. By enabling ex vivo biophysical analyses of nucleic acid acetylation in its physiological sequence context, these studies establish a chemical foundation for understanding the function of a universally conserved nucleobase in biology and disease.

Evolution and structural variations in chloroplast tRNAs in gymnosperms

Background

Chloroplast transfer RNAs (tRNAs) can participate in various vital processes. Gymnosperms have important ecological and economic value, and they are the dominant species in forest ecosystems in the Northern Hemisphere. However, the evolution and structural changes in chloroplast tRNAs in gymnosperms remain largely unclear.

Results

In this study, we determined the nucleotide evolution, phylogenetic relationships, and structural variations in 1779 chloroplast tRNAs in gymnosperms. The numbers and types of tRNA genes present in the chloroplast genomes of different gymnosperms did not differ greatly, where the average number of tRNAs was 33 and the frequencies of occurrence for various types of tRNAs were generally consistent. Nearly half of the anticodons were absent. Molecular sequence variation analysis identified the conserved secondary structures of tRNAs. About a quarter of the tRNA genes were found to contain precoded 3′ CCA tails. A few tRNAs have undergone novel structural changes that are closely related to their minimum free energy, and these structural changes affect the stability of the tRNAs. Phylogenetic analysis showed that tRNAs have evolved from multiple common ancestors. The transition rate was higher than the transversion rate in gymnosperm chloroplast tRNAs. More loss events than duplication events have occurred in gymnosperm chloroplast tRNAs during their evolutionary process.

Conclusions

These findings provide novel insights into the molecular evolution and biological characteristics of chloroplast tRNAs in gymnosperms.

Supplementary Information

The online version contains supplementary material available at 10.1186/s12864-021-08058-3.

History of tRNA research in strasbourg

The tRNA molecules, in addition to translating the genetic code into protein and defining the second genetic code via their aminoacylation by aminoacyl-tRNA synthetases, act in many other cellular functions and dysfunctions. This article, illustrated by personal souvenirs, covers the history of ~60 years tRNA research in Strasbourg. Typical examples point up how the work in Strasbourg was a two-way street, influenced by and at the same time influencing investigators outside of France. All along, research in Strasbourg has nurtured the structural and functional diversity of tRNA. It produced massive sequence and crystallographic data on tRNA and its partners, thereby leading to a deeper physicochemical understanding of tRNA architecture, dynamics, and identity. Moreover, it emphasized the role of nucleoside modifications and in the last two decades, highlighted tRNA idiosyncrasies in plants and organelles, together with cellular and health-focused aspects. The tRNA field benefited from a rich local academic heritage and a strong support by both university and CNRS. Its broad interlinks to the worldwide community of tRNA researchers opens to an exciting future. © 2019 IUBMB Life, 2019 © 2019 IUBMB Life, 71(8):1066-1087, 2019.

Predicting and modeling RNA architecture

A general approach for modeling the architecture of large and structured RNA molecules is described. The method exploits the modularity and the hierarchical folding of RNA architecture that is viewed as the assembly of preformed double-stranded helices defined by Watson-Crick base pairs and RNA modules maintained by non-Watson-Crick base pairs. Despite the extensive molecular neutrality observed in RNA structures, specificity in RNA folding is achieved through global constraints like lengths of helices, coaxiality of helical stacks, and structures adopted at the junctions of helices. The Assemble integrated suite of computer tools allows for sequence and structure analysis as well as interactive modeling by homology or ab initio assembly with possibilities for fitting within electronic density maps. The local key role of non-Watson-Crick pairs guides RNA architecture formation and offers metrics for assessing the accuracy of three-dimensional models in a more useful way than usual root mean square deviation (RMSD) values.

L-arginine influences the structure and function of arginase mRNA in Aspergillus nidulans

Expression of the arginase structural gene (agaA) in Aspergillus nidulans is subject to complex transcriptional and post-transcriptional regulation. Arginase mRNA has a long 5'-UTR sequence. Analysis of this sequence in silico revealed its putative complex secondary structure, the presence of arginine-binding motifs (arginine aptamers) and a short intron with two potential 3' splicing sites. In this report we present evidence that L-arginine (i) binds directly to the arginase 5'-UTR; (ii) invokes drastic changes in the secondary structure of the 5'-UTR, unlike several other L-amino acids and D-arginine; and (iii) forces the selection of one of two 3' splice sites of an intron present in the 5'-UTR. We postulate that expression of the eukaryotic structural gene coding for arginase in A. nidulans is regulated at the level of mRNA stability, depending on riboswitch-mediated alternative splicing of the 5'-UTR intron.

Shuffling of discrete tRNASer regions reveals differently utilized identity elements in yeast and methanogenic archaea

Seryl-tRNA synthetases (SerRSs) from methanogenic archaea possess distinct evolutionary origin and show minimal sequence similarity with counterparts from bacteria, eukaryotes and other archaea. Here we show that SerRS from yeast Saccharomyces cerevisiae and archaeon Methanococcus maripaludis (ScSerRS and MmSerRS, respectively) display significantly different ability to serylate heterologous tRNA(Ser). Recognition in yeast was shown to be more stringent than in archaeon. While cross-aminoacylation of M. maripaludis tRNA(Ser) (MmtRNA(Ser)) by yeast SerRS barely occurs, yeast tRNA(Ser) (SctRNA(Ser)) was shown to be a good substrate for heterologous MmSerRS. To investigate the contribution of different tRNA regions for the recognition by yeast and archaeal SerRS, chimeric tRNAs bearing separated domains of SctRNA(Ser) in MmtRNA(Ser) framework were produced by in vitro transcription and subjected to kinetic and gel mobility shift analysis with both enzymes. Generally, the recognition in M. maripaludis seems to be relatively relaxed toward tertiary elements of tRNA(Ser) structure and relies on the direct recognition of identity nucleotides. On the other hand, expression of tRNA(Ser) identity elements in yeast seems to be more sensitive toward surrounding sequence context. In both systems variable arm of tRNA was recognized as a major identity region with a strong influence on SerRS:tRNA binding. Acceptor domain of SctRNA(Ser) was also shown to be important for serylation in yeast. We propose that cognate interactions between N-terminal domain of yeast SerRS and variable region of SctRNA(Ser) place the acceptor stem into the enzyme's active site and lead to increased affinity toward serine and efficient serylation of tRNA. The same effect was not observed in M. maripaludis. Unlike its yeast counterpart, MmSerRS forms only one type of covalent complex with MmtRNA(Ser), regardless of the tRNA/SerRS molar ratio. Stoichiometry of the complex, one tRNA per dimeric SerRS, was revealed by mass spectrometry. Our studies indicate that different SerRS:tRNA recognition mode is utilized by these two systems.

Topology of three-way junctions in folded RNAs

The three-way junctions contained in X-ray structures of folded RNAs have been compiled and analyzed. Three-way junctions with two helices approximately coaxially stacked can be divided into three main families depending on the relative lengths of the segments linking the three Watson-Crick helices. Each family has topological characteristics with some conservation in the non-Watson-Crick pairs within the linking segments as well as in the types of contacts between the segments and the helices. The most populated family presents tertiary interactions between two helices as well as extensive shallow/minor groove contacts between a linking segment and the third helix. On the basis of the lengths of the linking segments, some guidelines could be deduced for choosing a topology for a three-way junction on the basis of a secondary structure. Examples and prediction bas'ed on those rules are discussed.

Bacillus subtilis tRNA(Pro) with the anticodon mo5UGG can recognize the codon CCC

In Bacillus subtilis, four codons, CCU, CCC, CCA, and CCG, are used for proline. There exists, however, only one proline-specific tRNA having the anticodon mo(5)UGG. Here, we found that this tRNA(Pro)(mo(5)UGG) can read not only the codons CCA, CCG and CCU but also CCC, using an in vitro assay system. This means that the first nucleoside of its anticodon, 5-methoxyuridine (mo(5)U), recognizes A, G, U and C. On the other hand, it was reported that mo(5)U at the first position of the anticodon of tRNA(Val)(mo(5)UAC) can recognize A, G, and U but not C. A comparison of the structure of the anticodon stem and loop of tRNA(Pro)(mo(5)UGG) with those of other tRNAs containing mo(5)U at the first positions of the anticodons suggests that a modification of nucleoside 32 to pseudouridine (Psi) enables tRNA(Pro)(mo(5)UGG) to read the CCC codon.

Towards understanding human mitochondrial leucine aminoacylation identity

Specific recognition of tRNAs by aminoacyl-tRNA synthetases is governed by sets of aminoacylation identity elements, well defined for numerous prokaryotic systems and eukaryotic cytosolic systems. Only restricted information is available for aminoacylation of human mitochondrial tRNAs, despite their particularities linked to the non-classical structures of the tRNAs and their involvement in a growing number of human neurodegenerative disorders linked to mutations in the corresponding tRNA genes. A major difficulty to be overcome is the preparation of active in vitro transcripts enabling a rational mutagenic analysis, as is currently performed for classical tRNAs. Here, structural and aminoacylation properties of in vitro transcribed tRNA(Leu(UUR)) are presented. Solution probing using a combination of enzymatic and chemical tools revealed only partial folding into an L-shaped structure, with an acceptor branch but with a floppy anticodon branch. Optimization of aminoacylation conditions allowed charging of up to 75% of molecules, showing that, despite its partially relaxed structure, in vitro transcribed tRNA(Leu(UUR)) is able to adapt to the synthetase. In addition, mutational analysis demonstrates that the discriminator base as well as residue A14 are important leucine identity elements. Thus, human mitochondrial leucylation is dependent on rules similar to those that apply in Escherichia coli. The impact of a subset of pathology-related mutations on aminoacylation and on tRNA structure, has been explored. These variants do not show significant structural rearrangements and either do not affect aminoacylation (mutations T3250C, T3271C, C3303T) or lead to marked effects. Interestingly, two variants with a mutation at the same position (A3243G and A3243T) lead to markedly different losses in aminoacylation efficiencies (tenfold and 300-fold, respectively).

tRNA1Ser(G34) with the anticodon GGA can recognize not only UCC and UCU codons but also UCA and UCG codons

The tRNA1Ser (anticodon VGA, V=uridin-5-oxyacetic acid) is essential for translation of the UCA codon in Escherichia coli. Here, we studied the translational abilities of serine tRNA derivatives, which have different bases from wild type at the first positions of their anticodons, using synthetic mRNAs containing the UCN (N=A, G, C, or U) codon. The tRNA1Ser(G34) having the anticodon GGA was able to read not only UCC and UCU codons but also UCA and UCG codons. This means that the formation of G-A or G-G pair allowed at the wobble position and these base pairs are noncanonical. The translational efficiency of the tRNA1Ser(G34) for UCA or UCG codon depends on the 2'-O-methylation of the C32 (Cm). The 2'-O-methylation of C32 may give rise to the space necessary for G-A or G-G base pair formation between the first position of anticodon and the third position of codon.

Mutation spectra in supF: approaches to elucidating sequence context effects

Shuttle vectors carrying the supF suppressor tRNA gene were originally developed for mutagenesis experiments in primate and human cells. Since then, the supF gene has been used as a mutation reporter in other mammalian cells, yeast, Escherichia coli, and transgenic mice. The widespread use of the vector for studies of many DNA reactive agents has produced a large database of mutation spectra. These provide primary information on the kinds and distribution of mutations provoked by many agents and, in many instances, allow comparisons between related agents or the same agent in different cell backgrounds. In this review we will discuss some of these data with a primary focus on the interpretation of UV mutation spectra. We will also describe our development and application of custom supF marker genes as an approach to studying the effect of sequence context on mutation hotspots and cold spots. Our studies suggest that C-C photoproducts are not mutagenic in certain sequence contexts in which T-C photoproducts are mutation hotspots. In addition, we have found several examples of sequence context effects acting as much as 80 bases away from the site of mutation. We will consider some of the problems raised by these studies and the possible resolution of some of them offered by the newly discovered family of damage bypass DNA polymerases.

tRNA leucine identity and recognition sets

Transfer RNAs (tRNAs) are grouped into two classes based on the structure of their variable loop. In Escherichia coli, tRNAs from three isoaccepting groups are classified as type II. Leucine tRNAs comprise one such group. We used both in vivo and in vitro approaches to determine the nucleotides that are required for tRNA(Leu) function. In addition, to investigate the role of the tRNA fold, we compared the in vivo and in vitro characteristics of type I tRNA(Leu) variants with their type II counterparts.A minimum of six conserved tRNA(Leu) nucleotides were required to change the amino acid identity and recognition of a type II tRNA(Ser) amber suppressor from a serine to a leucine residue. Five of these nucleotides affect tRNA tertiary structure; the G15-C48 tertiary "Levitt base-pair" in tRNA(Ser) was changed to A15-U48; the number of nucleotides in the alpha and beta regions of the D-loop was changed to achieve the positioning of G18 and G19 that is found in all tRNA(Leu); a base was inserted at position 47n between the base-paired extra stem and the T-stem; in addition the G73 "discriminator" base of tRNA(Ser) was changed to A73. This minimally altered tRNA(Ser) exclusively inserted leucine residues and was an excellent in vitro substrate for LeuRS. In a parallel experiment, nucleotide substitutions were made in a glutamine-inserting type I tRNA (RNA(SerDelta); an amber suppressor in which the tRNA(Ser) type II extra-stem-loop is replaced by a consensus type I loop). This "type I" swap experiment was successful both in vivo and in vitro but required more nucleotide substitutions than did the type II swap. The type I and II swaps revealed differences in the contributions of the tRNA(Leu) acceptor stem base-pairs to tRNA(Leu) function: in the type I, but not the type II fold, leucine specificity was contingent on the presence of the tRNA(Leu) acceptor stem sequence. The type I and II tRNAs used in this study differed only in the sequence and structure of the variable loop. By altering this loop, and thereby possibly introducing subtle changes into the overall tRNA fold, it became possible to detect otherwise cryptic contributions of the acceptor stem sequence to recognition by LeuRS. Possible reasons for this effect are discussed.

The Candida albicans CUG-decoding ser-tRNA has an atypical anticodon stem-loop structure

In many Candida species, the leucine CUG codon is decoded by a tRNA with two unusual properties: it is a ser-tRNA and, uniquely, has guanosine at position 33 (G33). Using a combination of enzymatic (V1 RNase, RnI nuclease) and chemical (Pb(2+), imidazole) probing of the native Candida albicans ser-tRNACAG, we demonstrate that the overall tertiary structure of this tRNA resembles that of a ser-tRNA rather than a leu-tRNA, except within the anticodon arm where there is considerable disruption of the anticodon stem. Using non-modified in vitro transcripts of the C. albicans ser-tRNACAG carrying G, C, U or A at position 33, we demonstrate that it is specifically a G residue at this position that induces the atypical anticodon stem structure. Further quantitative evidence for an unusual structure in the anticodon arm of the G33-tRNA is provided by the observed change in kinetics of methylation of the G at position 37, by purified Escherichia coli m(1)G37 methyltransferase. We conclude that the anticodon arm distortion, induced by a guanosine base at position 33 in the anticodon loop of this novel tRNA, results in reduced decoding ability which has facilitated the evolution of this tRNA without extinction of the species encoding it.

Minimal tRNA(Ser) and tRNA(Sec) substrates for human seryl-tRNA synthetase: contribution of tRNA domains to serylation and tertiary structure

The recognition process of tRNA(Ser) and tRNA(Sec) by human seryl-tRNA synthetase (SerRS) was studied using T7 transcripts representing defined regions of human tRNA(Ser) or tRNA(Sec) and the influence of the tRNA elements on serylation and tertiary structure was elucidated. The anticodon arms of both tRNAs showed no contribution to serylation in contrast to the acceptor stems and the long extra arms. D and T arms were only involved in formation of the L-shaped tRNA structure, not in the recognition process between tRNAs and SerRS. This is the first report of microhelices adapted from human tRNAs being aminoacylated by their homologous synthetase.

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

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

Regulation of substrate recognition by the MiaA tRNA prenyltransferase modification enzyme of Escherichia coli K-12

We purified polyhistidine (His6)-tagged and native Escherichia coli MiaA tRNA prenyltransferase, which uses dimethylallyl diphosphate (DMAPP) to isopentenylate A residues adjacent to the anticodons of most tRNA species that read codons starting with U residues. Kinetic and binding studies of purified MiaA were performed with several substrates, including synthetic wild-type tRNAPhe, the anticodon stem-loop (ACSLPhe) of tRNAPhe, and bulk tRNA isolated from a miaA mutant. Gel filtration shift and steady-state kinetic determinations showed that affinity-purified MiaA had the same properties as native MiaA and was completely active for tRNAPhe binding. MiaA had a Kmapp (tRNA substrates) approximately 3 nM, which is orders of magnitude lower than that of other purified tRNA modification enzymes, a Kmapp (DMAPP) = 632 nM, and a kcatapp = 0.44 s-1. MiaA activity was minimally affected by other modifications or nonsubstrate tRNA species present in bulk tRNA isolated from a miaA mutant. MiaA modified ACSLPhe with a kcatapp/Kmapp substrate specificity about 17-fold lower than that for intact tRNAPhe, mostly due to a decrease in apparent substrate binding affinity. Quantitative Western immunoblotting showed that MiaA is an abundant protein in exponentially growing bacteria (660 monomers per cell; 1.0 microM concentration) and is present in a catalytic excess. However, MiaA activity was strongly competitively inhibited for DMAPP by ATP and ADP (Kiapp = 0.06 microM), suggesting that MiaA activity is inhibited substantially in vivo and that DMAPP may bind to a conserved P-loop motif in this class of prenyltransferases. Band shift, filter binding, and gel filtration shift experiments support a model in which MiaA tRNA substrates are recognized by binding tightly to MiaA multimers possibly in a positively cooperative way (Kdapp approximately 0.07 microM).

Only one nucleotide insertion to the long variable arm confers an efficient serine acceptor activity upon Saccharomyces cerevisiae tRNA(Leu) in vitro

Several tRNA species have a long variable arm composed of over ten nucleotides, which are relevant to those specific to serine, leucine and tyrosine in prokaryotes, while there are only serine and leucine-specific tRNAs in eukaryotes. To clarify the evolutionary aspects of the identity determination mechanism of these tRNAs, the tRNA(Ser) recognition in Saccharomyces cerevisiae was studied. Unmodified tRNA(Leu) transcript had serylation ability of low efficiency, but native tRNA(Leu) did not, indicating that some modification of tRNA(Leu) serves as a negative identity determinant for seryl-tRNA synthetase. Changing the discriminator base did not seriously affect the serine accepting efficiency. The tRNA(Leu) transcript possessing the variable arm of tRNA(Ser) was efficiently aminoacylated with serine. Eventually, it was found that only one nucleotide insertion to the variable arm of tRNA(Leu) was sufficient to confer an efficient serine accepting activity. The mode of serine tRNA recognition is similar to that in Escherichia coli in that the end of the long variable arm, but not the anticodon or discriminator base, is important. However, S. cerevisiae seryl-tRNA synthetase adopts a substantially different mechanism for rejection of tRNA(Leu) from that of its E. coli counterpart.

Probing the 3' UTR structure of U1A mRNA and footprinting analysis of its complex with U1A protein

The structure of the conserved region of the U1A pre-mRNA (AgRNA) and its complex with U1A protein was investigated. The previously proposed secondary structure of Ag RNA, derived from enzymatic probing and analysis of the structure and function of mutant mRNAs, is now confirmed by chemical probing data and further refined in the regions where the enzymatic data were not conclusive. The two unpaired nucleotides in the internal loops opposite of the Box sequences as well as the tetraloop could not be cleaved by ribonucleases, but are accessible to chemical probes. Concerning the RNA-protein complex, the protection experiments showed that the Box regions are largely protected when the U1A protein is present. All stem regions in the 5' part of the structure seem protected against ribonucleases. Unexpectedly, the nucleotides of the tetraloop become accessible to ribonucleases in the RNA-protein complex. This result indicates that the tetraloop undergoes a conformational change upon U1A protein binding. The 3' part of the Ag RNA sequence, containing the polyadenylation signal in a hairpin structure, showed hardly any protection, a finding that agrees with the fact that U1A does not interfere with the binding of the cleavage polyadenylation specificity factor (CPSF) to the polyadenylation signal.

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.

Usefulness of functional and structural solution data for the modeling of tRNA-like structures

Structures of large RNAs are not easily solved by X-ray crystallography or by NMR spectroscopy. This paper reviews the alternate methodology based on enzymatic and chemical mapping data collected on RNAs combined with graphical modeling for the construction of three-dimensional models. The different steps that lead to the establishment of the models are critically discussed. It is shown how the correctness of an RNA model can be strengthened by establishing correlations between the structure and the functionality of the molecule and its variants. Finally, the predictive potential of a model is discussed The approach is illustrated by results obtained on plant viral tRNA-like structures, and particularly on that of brome mosaic virus (BMV) RNA.

Selection of aminoacyl-tRNAs at sense codons: the size of the tRNA variable loop determines whether the immediate 3' nucleotide to the codon has a context effect

Codon context can affect translational efficiency by several molecular mechanisms. The base stacking interactions between a codon-anticodon complex and the neighboring nucleotide immediately 3' can facilitate translation by amber suppressors and the tRNA structure is also known to modulate the sensitivity to context. In this study the relative rates of aminoacyl-tRNA selection were measured at four sense codons (UGG, CUC, UUC and UCA), in all four 3' nucleotide contexts, through direct competition with a programmed frameshift at a site derived from the release factor 2 gene. Two codons (UGG and UUC) are read by tRNAs with small variable regions and their rates of aminoacyl-tRNA selection correlated with the potential base stacking strength of the 3' neighboring nucleotide. The other two codons (CUC and UCA) are read by tRNAs with large variable regions and the rate of selection of the aminoacyl-tRNAs in these cases varied little among the four contexts. Re-examination of published data on amber suppression also revealed an inverse correlation between context sensitivity and the size of the variable region. Collectively the data suggest that a large variable loop in a tRNA decreases the influence of the 3' context on tRNA selection, probably by strengthening tRNA-ribosomal interactions.

Seryl-tRNA synthetase from Escherichia coli: functional evidence for cross-dimer tRNA binding during aminoacylation

Escherichia coli seryl-tRNA synthetase (SerRS) is a homo-dimeric class II aminoacyl-tRNA synthetase. Each subunit is composed of two distinct domains: the N-terminal domain is a 60 A long, arm-like coiled coil structure built up of two antiparallel alpha-helices, whereas the C-terminal domain, the catalytic core, is an alpha-beta structure overlying a seven-stranded antiparallel beta-sheet. Deletion of the arm-like domain (SerRS delta 35-97) does not affect the amino acid activation step of the reaction, but reduces aminoacylation activity by more than three orders of magnitude. In the present study, it was shown that the formation of heterodimers from two aminoacylation defective homodimers, the N-terminal deletion and an active site mutant (SerRS E355Q), restored charging activity. The aminoacylation activity in a mixture containing the heterodimers was compared to that of solutions containing the same concentrations of homodimer. The activity of the mixture was eight times higher than the activities of the homodimer solutions, and reached 50% of the theoretical value that would be expected if 50% of the mixture was in the heterodimer form and assuming that a heterodimer contains only one active site. These results are in full agreement with the structural analysis of E. coli SerRS complexed with its cognate tRNA and provide functional evidence for the cross-dimer binding of tRNA in solution.

A genetic algorithm based molecular modeling technique for RNA stem-loop structures

A new modeling technique for arriving at the three dimensional (3-D) structure of an RNA stem-loop has been developed based on a conformational search by a genetic algorithm and the following refinement by energy minimization. The genetic algorithm simultaneously optimizes a population of conformations in the predefined conformational space and generates 3-D models of RNA. The fitness function to be optimized by the algorithm has been defined to reflect the satisfaction of known conformational constraints. In addition to a term for distance constraints, the fitness function contains a term to constrain each local conformation near to a prepared template conformation. The technique has been applied to the two loops of tRNA, the anticodon loop and the T-loop, and has found good models with small root mean square deviations from the crystal structure. Slightly different models have also been found for the anticodon loop. The analysis of a collection of alternative models obtained has revealed statistical features of local variations at each base position.

Three-dimensional working model of M1 RNA, the catalytic RNA subunit of ribonuclease P from Escherichia coli

A three-dimensional model of M1 RNA, the catalytic RNA subunit of RNase P from Escherichia coli, was constructed with the aid of a computer. The modeling process took into account data from chemical and enzymatic protection experiments, phylogenetic analysis, studies of the activities of mutants, and the kinetics of reactions catalyzed by the binding of substrate to M1 RNA. The model provides a plausible picture of the binding to M1 RNA of the tRNA domain of a precursor tRNA substrate. The scissile bond and adjacent segments of the aminoacyl acceptor stem of a precursor tRNA substrate can fit into a cleft that leads to the phylogenetically conserved, central part of the structure.

The 2.9 A crystal structure of T. thermophilus seryl-tRNA synthetase complexed with tRNA(Ser)

The crystal structure of Thermus thermophilus seryl-transfer RNA synthetase, a class 2 aminoacyl-tRNA synthetase, complexed with a single tRNA(Ser) molecule was solved at 2.9 A resolution. The structure revealed how insertion of conserved base G20b from the D loop into the core of the tRNA determines the orientation of the long variable arm, which is a characteristic feature of most serine specific tRNAs. On tRNA binding, the antiparallel coiled-coil domain of one subunit of the synthetase makes contacts with the variable arm and T psi C loop of the tRNA and directs the acceptor stem of the tRNA into the active site of the other subunit. Specificity depends principally on recognition of the shape of tRNA(Ser) through backbone contacts and secondarily on sequence specific interactions.

Coexpression of eukaryotic tRNASer and yeast seryl-tRNA synthetase leads to functional amber suppression in Escherichia coli

In order to gain insight into the conservation of determinants for tRNA identity between organisms, Schizosaccharomyces pombe and human amber suppressor serine tRNA genes have been examined for functional expression in Escherichia coli. The primary transcripts, which originated from E. coli plasmid promoters, were processed into mature tRNAs, but they were poorly aminoacylated in E. coli and thus were nonfunctional as suppressors in vivo. However, coexpression of cloned Saccharomyces cerevisiae seryl-tRNA synthetase led to efficient suppression in E. coli. This shows that some, but not all, determinants specifying the tRNASer identity are conserved in evolution.

The long extra arms of human tRNA((Ser)Sec) and tRNA(Ser) function as major identify elements for serylation in an orientation-dependent, but not sequence-specific manner

Selenocysteine tRNA [tRNA((Ser)Sec)] is charged with serine by the same seryl-tRNA synthetase (SerRS) as the canonical serine tRNAs. Using site-directed mutagenesis, we have introduced a series of mutations into human tRNA((Ser)Sec) and tRNA(Ser) in order to study the identity elements of tRNA((Ser)Sec) for serylation and the effect of the orientation of the extra arm. Our results show that the long extra arm is one of the major identity elements for both tRNA(Ser) and tRNA((Ser)Sec) and gel retardation assays reveal that it appears to be a prerequisite for binding to the cognate synthetase. The long extra arm functions in an orientation-dependent, but not in a sequence-specific manner. The discriminator base G73 is another important identity element of tRNA((Ser)Sec), whereas the T- and D-arms play a minor role for the serylation efficiency.

Contributions of discrete tRNA(Ser) domains to aminoacylation by E.coli seryl-tRNA synthetase: a kinetic analysis using model RNA substrates

The aminoacylation kinetics of T7 transcripts representing defined regions of Escherichia coli serine tRNAs were determined using purified E.coli seryl-tRNA synthetase (SerRS) and the kinetic values were used to estimate the relative contribution of various tRNA(Ser) domains to recognition by SerRS. The analysis revealed that the extra stem/loop structure, characteristic of type II tRNAs such as tRNA(Ser), is the domain which makes the largest contribution to kcat/Km of aminoacylation. Moreover, Km of aminoacylation was increased by a factor of about 1000 when the extra stem/loop was changed to the consensus sequence of type I tRNA extra loops indicating that the stem structure contributes significantly to the binding of tRNA(Ser) to SerRS. A model RNA, which represents only the tRNA(Ser) coaxial acceptor-T psi C stem/loop domain, was also specifically aminoacylated by SerRS having a kcat/Km about 1000-fold greater than background levels. A significant portion of the contribution of this domain to aminoacylation is attributable to the acceptor stem sequence making the acceptor stem the second most important domain for recognition by SerRS. Finally, kcat/Km was essentially unchanged when the entire anticodon stem/loop of tRNA(Ser) was deleted indicating that neither the anticodon nucleotides nor the surrounding stem/loop structure are important for recognition by SerRS.

Yeast seryl-tRNA synthetase expressed in Escherichia coli recognizes bacterial serine-specific tRNAs in vivo

The Saccharomyces cerevisiae serS gene which encodes seryl-tRNA synthetase (SerRS) was expressed in Escherichia coli from the promoter and the ribosome binding sequences contained in its own 5'-flanking region. The low level of yeast SerRS in the prokaryotic host was sufficient to permit in vivo complementation of two temperature-sensitive E. coli serS mutants at the nonpermissive temperature. Thus, yeast SerRS can aminoacylate E. coli tRNA(Ser) species in vivo. Yeast SerRS, isolated from an overexpressing E. coli strain by a rapid two-step purification on FPLC, aminoacylated E. coli tRNA with serine much more poorly (relative kcat/Km = 2 x 10(-4)) than its homologous tRNAs. DL-Serine hydroxamate, an inhibitor of E. coli SerRS, inhibits yeast SerRS in vivo and in vitro with an inhibition constant (Ki) of 2.7 mM, a value 90-fold higher than that for E. coli SerRS.

Unique secondary and tertiary structural features of the eucaryotic selenocysteine tRNA(Sec)

Cotranslational insertion of selenocysteine into selenoenzymes is mediated by a specialized transfer RNA, the tRNA(Sec). We have carried out the determination of the solution structure of the eucaryotic tRNA(Sec). Based on the enzymatic and chemical probing approach, we show that the secondary structure bears a few unprecedented features like a 9 bp aminoacid-, a 4 bp thymine- and a 6 bp dihydrouridine-stems. Surprisingly, the eighth nucleotide, although being a uridine, is base-paired and cannot therefore correspond to the single-stranded invariant U8 found in all tRNAs. Rather, experimental evidence led us to propose that the role of the invariant U8 is actually played by the tenth nucleotide which is an A, numbered A8 to indicate this fact. The experimental data therefore demonstrate that the cloverleaf structure we derived experimentally resembles the hand-folded model proposed by Böck et al (ref. 3). Using the solution data and computer modelling, we derived a three-dimensional structure model which shows some unique aspects. Basically, A8, A14, U21 form a novel type of tertiary interaction in which A8 interacts with the Hoogsteen sites of A14 which itself forms a Watson-Crick pair with U21. No coherent model containing the canonical 15-48 interaction could be derived. Thus, the number of tertiary interactions appear to be limited, leading to an uncoupling of the variable stem from the rest of the molecule.

Rye nuclease I as a tool for structural studies of tRNAs with large variable arms

A single-strand-specific nuclease from rye germ (Rn nuclease I) was used for secondary and tertiary structure investigations of tRNAs with large variable arms (class II tRNAs). We have studied the structure in solution of two recently sequenced tRNA(Leu): yeast tRNA(Leu)(ncm5UmAA) and bovine tRNA(Leu)(XmAA) as well as yeast tRNA(Leu)(UAG), tRNA(Leu)(m5CAA) and tRNA(Ser)(IGA). The latter is the only tRNA with a long variable arm for which the secondary and tertiary structure has already been studied by use of chemical probes and computer modelling. The data obtained in this work showed that the general model of class II tRNAs proposed by others for tRNA(Ser) can be extended to tRNAs(Leu) as well. However interesting differences in the structure of tRNAs(Leu) versus tRNA(Ser)(IGA) were also noticed. The main difference was observed in the accessibility of the variable loops to nucleolytic attack of Rn nuclease I: variable loops of all studied tRNA(Leu) species were cut by Rn nuclease I, while that of yeast tRNA(Ser)(IGA) was not. This could be due to differences in stability of the variable arms and the lengths of their loops which are 3 and 4 nucleotides in tRNA(Ser)(IGA) and tRNAs(Leu) respectively.

Non-canonical substrates of aminoacyl-tRNA synthetases: the tRNA-like structure of brome mosaic virus genomic RNA

A 3-D model of the tyrosylable tRNA-like domain of the genomic brome mosaic virus RNAs was built by computer modelling based on solution probing of the molecule with different chemical and enzymatic reagents. This model encompasses four major structural domains, including two peculiar substructures oriented perpendicularly and mimicking a tRNA structure, and a fifth domain which makes the connection with the rest of the viral RNA. After recalling the different steps that led to the present structural knowledge of the BMV tRNA-like domain, we review its novel structural features revealed by the modelling and that did not appear in older versions of 3-D models of this structure. These features comprise additional base-pairs, hairpin loops, new tertiary long-range interactions, and a second pseudoknot. The main goal of this paper is to strengthen the validity of the model by establishing correlations between the putative 3-D conformation and the functional properties of the domain. For that, we show how the present structural model rationalises mutagenic and footprinting data that have established the importance of specific regions of the RNA for its recognition and aminoacylation by yeast tyrosyl-tRNA synthetase. We discuss further how the model corroborates mutational analyses performed to understand recognition of this RNA domain by the (ATP,CTP):tRNA nucleotidyl-transferase and by the viral replicase. The published mutants of the BMV tRNA-like domain fall into two classes. In one class, the mutants leave unchanged the overall architecture of the molecule, thereby affecting functions directly. In the second class, the overall architecture of the mutants is perturbed, and thus functions are affected indirectly.

Identifying constraints on the higher-order structure of RNA: continued development and application of comparative sequence analysis methods

Comparative sequence analysis addresses the problem of RNA folding and RNA structural diversity, and is responsible for determining the folding of many RNA molecules, including 5S, 16S, and 23S rRNAs, tRNA, RNAse P RNA, and Group I and II introns. Initially this method was utilized to fold these sequences into their secondary structures. More recently, this method has revealed numerous tertiary correlations, elucidating novel RNA structural motifs, several of which have been experimentally tested and verified, substantiating the general application of this approach. As successful as the comparative methods have been in elucidating higher-order structure, it is clear that additional structure constraints remain to be found. Deciphering such constraints requires more sensitive and rigorous protocols, in addition to RNA sequence datasets that contain additional phylogenetic diversity and an overall increase in the number of sequences. Various RNA databases, including the tRNA and rRNA sequence datasets, continue to grow in number as well as diversity. Described herein is the development of more rigorous comparative analysis protocols. Our initial development and applications on different RNA datasets have been very encouraging. Such analyses on tRNA, 16S and 23S rRNA are substantiating previously proposed associations and are now beginning to reveal additional constraints on these molecules. A subset of these involve several positions that correlate simultaneously with one another, implying units larger than a basepair can be under a phylogenetic constraint.

A tyrosyl-tRNA synthetase binds specifically to the group I intron catalytic core

The Neurospora CYT-18 protein, the mitochondrial tyrosyl-tRNA synthetase, functions in splicing group I introns in mitochondria. Here, we show that CYT-18 binds strongly to diverse group I introns that have minimal sequence homology and recognizes highly conserved structural features of the catalytic core of these introns. Inhibition experiments indicate that the intron RNA and tRNA(Tyr) compete for the same or overlapping binding sites in the CYT-18 protein. Considered together with functional analysis, our results indicate that the CYT-18 protein promotes splicing by binding to the intron core and stabilizing it in a conformation required for catalytic activity. Furthermore, the specific binding of the synthetase suggests that the group I intron catalytic core has structural similarities to tRNAs, which could reflect either convergent evolution or an evolutionary relationship between group I introns and tRNAs.

Nucleotide sequences of serine tRNAs from Bacillus subtilis

Three B. subitilis serine tRNAs were sequenced including modified nucleosides. All the serine tRNAs contained 1-methyl-adenosine in the D-loop. As other characteristic modified nucleosides, 5-methoxyuridine was found in the first letter of the anticodon in the tRNA(UGA).

Comparison of dissimilarity patterns of E coli, yeast and mammalian tRNAs

A number of experimental approaches have been developed for identification of recognition (identity) sites in tRNAs. Along with them a theoretical methodology has been proposed by McClain et al that is based on concomitant analysis of all tRNA sequences from a given species. This approach allows an evaluation of nucleotide combinations present in isoacceptor tRNAs specific for the given amino acid, and not present in equivalent positions in cloverleaf structure in other tRNAs of the same organism. These elements predicted from computer analysis of the databank could be tested experimentally for their participation in forming recognition sites. The correlation between theoretical predictions and experimental data appeared promising. The aim of the present work consisted of introducing further improvements into McClain's procedure by: i), introducing into analysis a variable region in tRNAs which had not been previously considered; to accomplish this, 'normalization' of variable nucleotides was suggested, based on primary and tertiary structures of tRNAs; ii), developing a new procedure for comparison of patterns for synonymous and non-synonymous tRNAs from different organisms; iii), analysis of 3- and 4-positional contacts between tRNAs and enzymes in addition to a formerly used 2-positional model. A systematic application of McClain's procedure to mammalian, yeast and E coli tRNAs led to the following results: i), imitancy patterns for non-synonymous tRNAs of any amino acid specificity and from any organisms analysed so far overlap by no more than 30%, providing a structural basis for discrimination with high fidelity between cognate and non-cognate tRNAs; ii), the predicted identity sites are non-randomly distributed within tRNA molecules; the dominant role is ascribed to only two regions--anticodon and amino acid stem which are located far apart from one another at extremes of all tRNA molecules; iii), the imitancy patterns for synonymous tRNAs in lower (yeast) and higher (mammalian) eukaryotes are similar but not identical; iv), distribution of predicted identity sites in the cloverleaf structure in prokaryotes and eukaryotes is essentially different: in eubacterial tRNAs the major role in recognition plays anticodon and/or amino acid acceptor stem, whereas in eukaryotic (both unicellular and multicellular) tRNAs the remaining part of the molecules is also involved in recognition; v), the imitancy patterns of synonymous tRNAs from prokaryotes and eukaryotes are dissimilar, this observation leads to the prediction that the tRNA identity sites for the same amino acid in prokaryotes and eukaryotes may differ.

Three-dimensional model of Escherichia coli ribosomal 5 S RNA as deduced from structure probing in solution and computer modeling

The conformation of Escherichia coli 5 S rRNA was investigated using chemical and enzymatic probes. The four bases were monitored at one of their Watson-Crick positions with dimethylsulfate (at C(N-3) and A(N-1], with a carbodiimide derivative (at G(N-1) and U(N-3] and with kethoxal (at G(N-1, N-2]. Position N-7 of purine was probed with diethylpyrocarbonate (at A(N-7] and dimethylsulfate (at G(N-7]. Double-stranded or stacked regions were tested with RNase V1 and unpaired guanine residues with RNase T1. We also used lead(II) that has a preferential affinity for interhelical and loop regions and a high sensitivity for flexible regions. Particular care was taken to use uniform conditions of salt, magnesium, pH and temperature for the different enzymatic chemical probes. Derived from these experimental data, a three dimensional model of the 5 S rRNA was built using computer modeling which integrates stereochemical constraints and phylogenetic data. The three domains of 5 S rRNA secondary structure fold into a Y-shaped structure that does not accommodate long-range tertiary interactions between domains. The three domains have distinct structural and dynamic features as revealed by the chemical reactivity and the lead(II)-induced hydrolysis: domain 2 (loop B/helix III/loop C) displays a rather weak structure and possesses dynamic properties while domain 3 (helix V/region E/helix IV/loop D) adopts a highly structured and overall helical conformation. Conserved nucleotides are not crucial for the tertiary folding but maintain an intrinsic structure in the loop regions, especially via non-canonical pairing (A.G, G.U, G.G, A.C, C.C), which can close the loops in a highly specific fashion. In particular, nucleotides in the large external loop C fold into an organized conformation leading to the formation of a five-membered loop motif. Finally, nucleotides at the hinge region of the Y-shape are involved in a precise array of hydrogen bonds based on a triple interaction between U14, G69 and G107 stabilizing the quasi-colinearity of helices II and V. The proposed tertiary model is consistent with the localization of the ribosomal protein binding sites and possesses strong analogy with the model proposed for Xenopus laevis 5 S rRNA, indicating that the Y-shape model can be generalized to all 5 S rRNAs.

Interaction of Escherichia coli tRNA(Ser) with its cognate aminoacyl-tRNA synthetase as determined by footprinting with phosphorothioate-containing tRNA transcripts

A footprinting technique using phosphorothioate-containing RNA transcripts has been developed and applied to identify contacts between Escherichia coli tRNA(Ser) and its cognate aminoacyl-tRNA synthetase. The cloned gene for the tRNA was transcribed in four reactions in which a different NTP was complemented by 5% of the corresponding nucleoside 5'-O-(1-thiotriphosphate). The phosphorothioate groups of such transcripts are cleaved by reaction with iodine to permit sequencing of the transcripts. Footprinting was achieved by performing the same reaction with the phosphorothioate-tRNA-enzyme complex. At 1 mM iodine, selective protection of the tRNA transcripts in the cognate system was observed, with strong protection at positions 52 and 68 and weak protection at positions 46, 53, 67, 69, and 70. It is suggested that these regions of the tRNA interact with the helical arm of the synthetase.

Conversion of aminoacylation specificity from tRNA(Tyr) to tRNA(Ser) in vitro

The discrimination mechanism between tRNA(Ser) and tRNA(Tyr) was studied using various in vitro transcripts of E. coli tRNATyr variants. The insertion of only two nucleotides into the variable stem of tRNA(Tyr) generates serine charging activity. The acceptor activities of some of the tRNA(Tyr) mutants with insertions in the long variable arm were enhanced by changes in nucleotides at positions 9 and/or 20B, which are possible elements for dictating the orientation of the long variable arm. These findings suggest that the long variable arm is involved in recognition by seryl-tRNA synthetase in spite of sequence and length variations shown within tRNA(Ser) isoacceptors, and eventually serves as a determinant for selection from other tRNA species. Changing the anticodon from GUA to the serine anticodon GGA resulted in a marked decrease in tyrosine charging activity, but this mutant did not show any serine charging activity. The discriminator base, the fourth base from the 3' end of tRNA, was also important for aminoacylation with tyrosine. Complete specificity change in vitro was facilitated by insertion of three nucleotides into the variable arm plus two nucleotide changes at positions 9 and 73.

Effect of mutations in domain 2 on the structural organization of oocyte 5 S rRNA from Xenopus laevis

In order to test and refine the molecular model of Xenopus laevis 5 S rRNA proposed in a previous work, we have synthesized, by site-directed mutagenesis and in vitro transcription, four mutants in the internal loop B and in the hairpin loop C of domain 2. The conformations of these mutant 5 S rRNAs have been tested using a variety of enzymatic and chemical structure-specific probes and computer modeling. The mutations induce conformational changes restricted to the mutated regions. Our results demonstrate unambiguously that the three helical domains of the Y-shaped structure are independent and that loop C possesses an intrinsic conformation, which is not involved in any tertiary long-range interaction. They point to the crucial role of invariant nucleotides in maintaining the intrinsic conformation of the loop and to the effect of sequence on the stability of loop regions.

Crosslinking of tRNA containing a long extra arm to elongation factor Tu by trans-diamminedichloroplatinum(II)

A tRNA containing a long extra arm, namely E. coli tRNA(Leu1) has been crosslinked to elongation factor Tu, with the crosslinking reagent trans-diamminedichloroplatinum(II). The nucleotide involved in the crosslinking was identified to be a guanosine in the variable region at position 47F or 47G.

Recognition of tRNA(Tyr) by tyrosyl-tRNA synthetase

In this review, I have brought together and compared the available data on the interaction between tRNA(Tyr) and tyrosyl-tRNA synthetases (TyrTS) of prokaryotic origins. The amino acid sequences of the heterologous TyrTS that can charge Escherichia coli tRNA(Tyr), show that the residues involved in the binding and recognition of tyrosine are strictly conserved whereas those involved in the interaction with tRNA(Tyr) are only weakly similar. The results of in vivo genetic complementation experiments indicate that the identity elements of tRNAs and the recognition mechanisms of such elements by the synthetases have been conserved during evolution. Heterologous or mutant tRNA(Tyr) are quantitatively charged by E coli TyrTS; the set of their common residues contains less than 10 elements if one excludes the invariant and semi-invariant residues of tRNAs. The residues of this set are candidates for a specific recognition by TyrTS. So far, adenosine-73 is the only residue for which a specific recognition of the base has been demonstrated. The residues that might serve as identity elements for E coli tRNA(Tyr) [McClain WH, Nicholas Jr HB (1987) J Mol Biol 194, 635-642] do not belong to the above set of conserved residues and therefore probably play negative roles, enabling tRNA(Tyr) to avoid non-cognate synthetases. Comparison of the charging and stability properties of mutant tRNA(Tyr) su +3 shows that bases 1 and 72 must pair (either by Watson-Crick or non-canonical hydrogen bonds) and adopt a geometry which is compatible with the helical structure of the acceptor stem in order for the mutant tRNA(Tyr) to be charged with tyrosine. If bases 1 and 72 or bases 2 and 71 cannot form such pairings, the suppressor phenotype of the mutant tRNA(Tyr)su +3 becomes thermosensitive. The weakening of base pair 1/72 by mutation or the change of adenosine-73 into guanosine results in the charging of tRNA(Tyr)su +3 with glutamine. Comparison of the structural model of the TyrTS/tRNA(Tyr) complex with the crystallographic structure of the GlnTS/tRNA(Gln) complex indicates that the mechanisms for the recognition of the acceptor arm are different in the 2 cases. Chemical attack and molecular modeling experiments have indicated that the acceptor end of tRNA(Tyr) ... CCCA3'-OH, remains mobile after the initial binding of tRNA(Tyr) to TyrTS.

Solution structure of human U1 snRNA. Derivation of a possible three-dimensional model

The solution structure of human U1 snRNA was investigated by using base-specific chemical probes (dimethylsulfate, carbodiimide, diethylpyrocarbonate) and RNase V1. Chemical reagents were employed under various conditions of salt and temperature and allowed information at the Watson-Crick base-pairing positions to be obtained for 66% of the U1 snRNA bases. Double-stranded or stacked regions were examined with RNase V1. The dat gained from these experiments extend and support the previous 2D model for U1snRNA. However, to elucidate some aspects of the solution data that could not be accounted for by the secondary structure model, the information gathered from structure probing was used to provide the experimental basis required to construct and to test a tertiary structure model by computer graphics modeling. As a result, U1 snRNA is shown to adopt an asymmetrical X-shape that is formed by two helical domains, each one being generated by coaxial stacking of helices at the U1 snRNA cruciform. Chemical reactivities and model building show that a few nucleotides, previously proposed to be unpaired, can form A.G and U.U non Watson-Crick base-pairs, notably in stem-loop B. The structural model we propose for regions G12 to A124 integrates stereochemical constraints and is based both on solution structure data and sequence comparisons between U1 snRNAs.

Solution conformation of several free tRNALeu species from bean, yeast and Escherichia coli and interaction of these tRNAs with bean cytoplasmic Leucyl-tRNA synthetase. A phosphate alkylation study with ethylnitrosourea

The solution conformation of eight leucine tRNAs from Phaseolus vulgaris, baker's yeast and Escherichia coli, characterized by long variable regions, and the interaction of four of them with bean cytoplasmic leucyl-tRNA synthetase were studied by phosphate mapping with ethylnitrosourea. Phosphate reactivities in the variable regions agree with the existence of RNA helices closed by miniloops. At the junction of these regions with the T-stem, phosphate 48 is strongly protected, in contrast to small variable region tRNAs where P49 is protected. The constant protection of P22 is another characteristics of leucine tRNAs. Conformational differences between leucine isoacceptors concern the anticodon region, the D-arm and the variable region. In several parts of free tRNALeu species, e.g. in the T-loop, phosphate reactivities are similar to those found in tRNAs of other specificities, indicating conformational similarities among tRNAs. Phosphate alkylation of four leucine tRNAs complexed to leucyl-tRNA synthetase indicates that the 3'-side of the anticodon stem, the D-stem and the hinge region between the anticodon and D-stems are in contact with the plant enzyme.