Evidence for helical unwinding of an RNA substrate by the RNA enzyme RNase P: use of an interstrand disulfide crosslink in substrate

To gain an understanding of structural changes induced in substrates by Escherichia coli ribonuclease P (RNase P), we have incorporated an interstrand disulfide crosslink proximal to the cleavage site in a model substrate. RNase P is able to process the reduced, non-crosslinked form of this substrate as well as a substrate in which the free thiol molecules have been alkylated with iodoacetamide. However, the oxidized, crosslinked form is cleaved at a significantly lower rate. Therefore, helical unwinding of the analog of the aminoacyl stem of the substrate near its site of cleavage may be necessary for efficient processing by E. coli RNase P.

tRNA-guanine transglycosylase from Escherichia coli: recognition of noncognate-cognate chimeric tRNA and discovery of a novel recognition site within the TpsiC arm of tRNA(Phe)

tRNA-guanine transglycosylase (TGT) is a key enzyme involved in the posttranscriptional modification of tRNA across the three kingdoms of life. In eukaryotes and eubacteria, TGT is involved in the introduction of queuine into the anticodon of the cognate tRNAs. In archaebacteria, TGT is responsible for the introduction of archaeosine into the D-loop of the appropriate tRNAs. The tRNA recognition patterns for the eubacterial (Escherichia coli) TGT have been studied. These studies are all consistent with a restricted recognition motif involving a U-G-U sequence in a seven-base loop at the end of a helix. While attempting to investigate the potential of negative recognition elements in noncognate tRNAs via the use of chimeric tRNAs, we have discovered a second recognition site for the E. coli TGT in the TpsiC arm of in vitro-transcribed yeast tRNA(Phe). Kinetic analyses of synthetic mutant oligoribonucleotides corresponding to the TpsiC arm of the yeast tRNA(Phe) indicate that the specific site of TGT action is G53 (within a U-G-U sequence at the transition of the TpsiC stem into the loop). Posttranscriptional base modifications in tRNA(Phe) block recognition by TGT, most likely due to a stabilization of the tRNA structure such that G53 is inaccessible to TGT. These results demonstrate that TGT can recognize the U-G-U sequence within a structural context that is different than the canonical U-G-U in the anticodon loop of tRNA(Asp). Although it is unclear if this second recognition site is physiologically relevant, this does suggest that other RNA species could serve as substrates for TGT in vivo.

Selection of functional tRNA primers and primer binding site sequences from a retroviral combinatorial library: identification of new functional tRNA primers in murine leukemia virus replication

Retroviral reverse transcription is initiated from a cellular tRNA molecule and all known exogenous isolates of murine leukemia virus utilise a tRNA(Pro)molecule. While several studies suggest flexibility in murine leukemia virus primer utilisation, studies on human immunodeficiency virus and avian retro-viruses have revealed evidence of molecular adapt-ation towards the specific tRNA isoacceptor used as replication primer. In this study, murine leukemia virus tRNA utilisation is investigated by in vivo screening of a retroviral vector combinatorial library with randomised primer binding sites. While most of the selected primer binding sites are complementary to the 3'-end of tRNA((Pro)), we also retrieved PBS sequences matching four other tRNA molecules and demonstrate that Akv murine leukemia virus vectors may efficiently replicate using tRNA(Arg(CCU)), tRNA(Phe(GAA))and a hitherto unknown human tRNA(Ser(CGA)).

Chloroplast DNA variation and reticulate evolution in sexual and apomictic sections of dandelions

Sequencing of the trnL-trnF intergenic spacer in chloroplast DNA (cpDNA) from 237 sexual and apomictic species of dandelions (genus Taraxacum) from Europe, Asia and arctic North America revealed 46 haplotypes, which differed mainly by a variable number of polymorphic tRNA pseudogenes next to the trnF gene. The haplotypes could be divided into 20 cpDNA lineages, but independent duplications and deletions of the pseudogene copies made it difficult to further reconstruct the phylogeny. Intraspecific cpDNA variation was found in the primitive sexual T. serotinum. However, in contrast to a recent study, no cpDNA variation was detected within 12 apomictic species representing a variety of haplotypes. The cpDNA haplotype may therefore help to define these critical apomicts. On the other hand, the genetic variation may easily be overestimated, if the clones are not correctly identified, because some morphologically similar microspecies carried very different haplotypes. In all, 36 sections of the genus were sampled. Four primitive, mainly sexual, sections only displayed a group of ancient haplotypes, whereas morphologically more advanced sections often exhibited many different haplotypes from up to seven cpDNA lineages. In the latter cases, the lineages were rarely unique to a certain section. For example, the two most widespread haplotypes, belonging to different lineages, were found together in nine sections. This suggests that significant gene flow has occurred among the advanced sections, although sexual reproduction is not currently known in several of them. The result is consistent with the reticulate distribution of morphological characters among the sections.

Pyrophosphate mediates the effect of certain tRNA mutations on aminoacylation of yeast tRNA(Phe)

The influence of pyrophosphate hydrolysis by inorganic pyrophosphatase on homologous aminoacylation of different yeast tRNA(Phe) mutants was studied. The addition of pyrophosphatase significantly improved the aminoacylation efficiency of tRNA(Phe) structural mutants as well as the mutant with substitution at position 20, while having no effect on the charge of wild-type tRNA(Phe). Aminoacylation of tRNA(Phe) anticodon and discriminator base (N(73)) mutants was not affected by pyrophosphatase. Activation of wild-type tRNA(Phe) transcript aminoacylation by inorganic pyrophosphatase was observed only at low Mg(2+) concentrations due to distortion of the tRNA(Phe) structure under these conditions. Our results demonstrate that pyrophosphate dissociation becomes a rate-limiting step of the reaction in yeast phenylalanyl-tRNA synthetase catalyzed aminoacylation of tRNA(Phe) variants with altered tertiary structure. A possible mechanism of pyrophosphate-mediated inhibition of tRNA mutants aminoacylation is discussed.

Design and isolation of ribozyme-substrate pairs using RNase P-based ribozymes containing altered substrate binding sites

Substrate recognition and cleavage by the bacterial RNase P RNA requires two domains, a specificity domain, or S-domain, and a catalytic domain, or C-domain. The S-domain binds the T stem-loop region in a pre-tRNA substrate to confer specificity for tRNA substrates. In this work, the entire S-domain of the Bacillus subtilis RNase P RNA is replaced with an artificial substrate binding module. New RNA substrates are isolated by in vitro selection using two libraries containing random regions of 60 nt. At the end of the selection, the cleavage rates of the substrate library are approximately 0.7 min(-1)in 10 mM MgCl(2)at 37 degrees C, approximately 4-fold better than the cleavage of a pre-tRNA substrate by the wild-type RNase P RNA under the same conditions. The contribution of the S-domain replacement to the catalytic efficiency is from 6- to 22 000-fold. Chemical and nuclease mapping of two ribozyme-product complexes shows that this contribution correlates with direct interactions between the S-domain replacement and the selected substrate. These results demonstrate the feasibility of design and isolation of RNase P-based, matching ribozyme-substrate pairs without prior knowledge of the sequence or structure of the interactive modules in the ribozyme or substrate.

Application of an improved cDNA competition technique to identify prostate cancer-associated gene

A technique to improve cDNA library screening was developed by using mixed probes derived from two closely related cDNA populations of high-metastatic MAT-LyLu and low-metastatic AT-1 Dunning R3227 rat prostate cancer sublines. The technique required the generation of a cDNA library from each subline followed by polymerase chain reaction (PCR) amplification of the cDNA insert population. The PCR products derived from the first library were radiolabeled and mixed with an excess amount of PCR products from the second library. The mixture and an excess amount of both the lambda and pBluescript DNA were used as a probe to screen the first cDNA library. This mixed probe (designated the competition probe) differentially cross-hybridized with the plaque lift of the screened first cDNA library. Weak radioactive signals indicated the cross-hybridization of cDNA sequences common to the competition probe mixture and the first cDNA library, whereas strong signals implied unhybridized unique or abundant cDNA sequences in the first cDNA library. The reproducibility of this technique was confirmed by showing that the full-length cDNA clones were associated with the phenotype of the screened first cell line. The isolated clones were characterized as rat nucleolar protein, rat mitochondrial genes coding for 16S and 12S rRNAs, and rat tRNAs specific for valine and phenyl-alanine. This result is consistent with the fact that the first cell line, MAT-LyLu, is metabolically more active than are AT-1 cells because of higher gene dosage or amplification of nucleolar and mitochondrial RNA and its associated genes. Another clone which had a strong signal represented a novel gene associated with the MAT-LyLu cancer phenotype.

Molecular evolution of a tandemly repeated trnF(GAA) gene in the chloroplast genomes of Microseris (Asteraceae) and the use of structural mutations in phylogenetic analyses

We sequenced the first ca. 900 bp of the 5'-trnL(UAA)-trnV(UAC)/ndhJ region of the chloroplast DNA of different Microseris accessions in order to resolve homoplasious length variation detected in the trnL(UAA)-trnF(GAA) region. We found two to four tandemly repeated trnF genes in the species of Microseris (Asteraceae, Lactuceae) and two in their sister genus Uropappus. Sequences indicated nonhomologous transitions between two, three, and four trnF genes in different Microseris taxa. Independent origins of similar trnF copy numbers were inferred from a chloroplast phylogeny of Microseris. The taxa involved grow on separate continents, supporting parallel origins of similar length variants. The changes in trnF copy numbers were best explained by interchromosomal recombination with unequal crossing over. The 5' copies of the repeats showed the highest sequence conservation, suggesting that these copies are likely to be functional trnF genes, whereas the other ones probably represent pseudogenes. Our results show that length polymorphisms accumulate once a duplicated sequence has become incorporated. Due to parallel gains of similar trnF copy numbers, homoplasious length variation was introduced into the data matrix. The data demonstrate that length polymorphisms cannot be used as indicators for phylogenetic distance unless they can be analyzed at the sequence level.

Induced fit in initial selection and proofreading of aminoacyl-tRNA on the ribosome

The fidelity of aminoacyl-tRNA (aa-tRNA) selection by the bacterial ribosome is determined by initial selection before and proofreading after GTP hydrolysis by elongation factor Tu. Here we report the rate constants of A-site binding of a near-cognate aa-tRNA. The comparison with the data for cognate aa-tRNA reveals an additional, important contribution to aa-tRNA discrimination of conformational coupling by induced fit. It is found that two rearrangement steps that limit the chemical reactions of A-site binding, i.e. GTPase activation (preceding GTP hydrolysis) and A-site accommodation (preceding peptide bond formation), are substantially faster for cognate than for near-cognate aa-tRNA. This suggests an induced-fit mechanism of aa-tRNA discrimination on the ribosome that operates in both initial selection and proofreading. It is proposed that the cognate codon-anticodon interaction, more efficiently than the near-cognate one, induces a particular conformation of the decoding center of 16S rRNA, which in turn promotes GTPase activation and A-site accommodation of aa-tRNA, thereby accelerating the chemical steps. As kinetically favored incorporation of the correct substrate has also been suggested for DNA and RNA polymerases, the present findings indicate that induced fit may contribute to the fidelity of template-programed systems in general.

Synthetase recognition determinants of E. coli valine transfer RNA

We have studied the interactions between Escherichia coli tRNAVal and valyl-tRNA synthetase (ValRS) by enzymatic footprinting with nuclease S1 and ribonuclease V1, and by analysis of the aminoacylation kinetics of mutant tRNAVal transcripts. Valyl-tRNA synthetase specifically protects the anticodon loop, the 3' side of the stacked T-stem/acceptor-stem helix, and the 5' side of the anticodon stem of tRNAVal against cleavage by double- and single-strand-specific nucleases. Increased nuclease susceptibility at the ends of the anticodon- and T-stems in the tRNAVal.ValRS complex is indicative of enzyme-induced conformational changes in the tRNA. The most important synthetase recognition determinants are the middle and 3' anticodon nucleotides (A35 and C36, respectively); G20, in the variable pocket, and G45, in the tRNA central core, are minor recognition elements. The discriminator base, position 73, and the anticodon stem also are recognized by ValRS. Replacing wild-type A73 with G73 reduces the aminoacylation efficiency more than 40-fold. However, the C73 and U73 mutants remain good substrates for ValRS, suggesting that guanosine at position 73 acts as a negative determinant. The amino acid acceptor arm of tRNAVal contains no other synthetase recognition nucleotides, but regular A-type RNA helix geometry in the acceptor stem is essential [Liu, M., et al. (1997) Nucleic Acids Res. 25, 4883-4890]. In the anticodon stem, converting the U29:A41 base pair to C29:G41 reduces the aminoacylation efficiency 50-fold. This is apparently due to the rigidity of the anticodon stem caused by the presence of five consecutive C:G base pairs, since the A29:U41 mutant is readily aminoacylated. Identity switch experiments provide additional evidence for a role of the anticodon stem in synthetase recognition. The valine recognition determinants, A35, C36, A73, G20, G45, and a regular A-RNA acceptor helix are insufficient to transform E. coli tRNAPhe into an effective valine acceptor. Replacing the anticodon stem of tRNAPhe with that of tRNAVal, however, converts the tRNA into a good substrate for ValRS. These experiments confirm G45 as a minor ValRS recognition element.

Hybridization of antisense oligonucleotides with the 3'part of tRNA(Phe)

The interaction of antisense oligodeoxyribonucleotides with yeast tRNA(Phe) was investigated. 14-15-mers complementary to the 3'-terminal sequence including the ACCA end bind to the tRNA under physiological conditions. At low oligonucleotide concentrations the binding occurs at the unique complementary site. At higher oligonucleotide concentrations, the second oligonucleotide molecule binds to the complex due to non-perfect duplex formation in the T-loop stabilized by stacking between the two bound oligonucleotides. In these complexes the acceptor stem is open and the 5'-terminal sequence of the tRNA is accessible for binding of a complementary oligonucleotide. The results prove that the efficient binding of oligonucleotides to the 3'-terminal sequence of the tRNA occurs through initial binding to the single-stranded sequence ACCA followed by invasion in the acceptor stem and strand displacement.

Recognition of a pre-tRNA substrate by the Bacillus subtilis RNase P holoenzyme

The holoenzyme of the bacterial RNase P has broader selectivity for biological substrates compared to the RNA alone (denoted P RNA) reaction. The structural basis of the substrate selectivity is investigated using a pre-tRNA substrate containing single-atom modifications by single turnover kinetics. Hydroxyl radical protection of the holoenzyme in the absence of the substrate shows that the RNase P protein binds to several regions in P RNA. The holoenzyme interacts with a subset of functional groups in the T stem-loop region of a pre-tRNA substrate previously identified to directly contact P RNA. The subtle change in structural recognition allows the holoenzyme to recognize RNA structures with only a small perturbation in an A-form helix at the corresponding position of the T stem-loop. This altered profile may permit the holoenzyme to bind non-tRNA substrates with little change in catalytic efficiency. The holoenzyme recognizes the same set of functional groups as the P RNA reaction in the region around the cleavage site and shows similar cleavage site selection compared to the P RNA reaction. These results suggest that the holoenzyme does not alter the fundamental mechanism of this enzymatic reaction. Rather, the holoenzyme significantly affects the binding affinity of an RNA substrate through additional interactions with the 5' leader [Kurz, C. A., Niranjanakumari, S., and Fierke, C. A. (1998) Biochemistry 37, 2393] and through altered recognition of the substrate structure.

Substrate recognition of tRNA (Guanosine-2'-)-methyltransferase from Thermus thermophilus HB27

Transfer RNA (guanosine-2'-)-methyltransferase (Gm-methylase, EC 2.1. 1.32) from Thermus thermophilus HB27 is one of the tRNA ribose modification enzymes. The broad substrate specificity of Gm-methylase has so far been elucidated using various species of tRNAs from native sources, suggesting that the common structures in tRNAs are recognized by the enzyme. In this study, by using 28 yeast tRNAPhe variants obtained by transcription with T7 RNA polymerase, it was revealed that the nucleotide residues G18 and G19 and the D-stem structure are essentially required for Gm-methylase recognition, and that the key sequence for the substrate is pyrimidine (Py)17G18G19. The other conserved sequences were found not to be essential, but U8, G15, G26, G46, U54, U55, and C56 considerably affected the methylation efficiency. These residues are located within a limited space embedded in the L-shaped three-dimensional structure of tRNA. Therefore, disruption of the three-dimensional structure of the substrate tRNA is necessary for the catalytic center of Gm-methylase to be able to access the target site in the tRNA, suggesting that the interaction of Gm-methylase with tRNA consists of multiple steps. This postulation was confirmed by inhibition experiments using nonsubstrate tRNA variants which functioned as competitive inhibitors against usual substrate tRNAs.

Affinity modification of phenylalanyl-tRNA synthetase from Thermus thermophilus by tRNAPhe transcripts containing 4-thiouridine

Photoreactive derivatives of tRNAPhe containing residues of 4-thiouridine (s4U) were synthesized by the transcription system of T7 RNA polymerase. Complete substitution of s4U for 16 uridine residues ([16s4U]-tRNAPhe) caused a 14-fold decrease in the catalytic efficiency of aminoacylation of the tRNAPhe transcript by phenylalanyl-tRNA synthetase from T. thermophilus. [1s4U]-tRNAPhe obtained by random incorporation of s4U residues with further isolation of s4U-monosubstituted RNA molecules on an affinity gel has the same kinetic parameters in aminoacylation as the tRNAPhe transcript. The s4U-containing tRNAPhe transcripts were shown to bind covalently to phenylalanyl-tRNA synthetase, and the specificity of modification was demonstrated. The modification stoichiometry determined in this work suggests that the enzyme is a functional dimer. The modification labels both alpha- and beta-subunits of the enzyme, which has an oligomeric structure of alpha2beta2, and forms "cross-linking" products of subunits upon modification with [16s4U]-tRNAPhe. The prevalence of modification of the alpha-subunit suggests that tRNA has contacts with the enzyme, which have not been deciphered previously by X-ray analysis.

Localization of the binding site for the 3'-terminal sequence of tRNAPhe in subunits of phenylalanyl-tRNA synthetase from Thermus thermophilus

A photoreactive tRNAPhe derivative containing a 4-thiouridine residue at the 3'-end (tRNAPhe-s4U-75) was prepared by tRNA nucleotidyltransferase-mediated incorporation of s4UMP into a tRNAPhe transcript lacking the 3'-terminal dinucleotide. The resulting tRNAPhe-s4U-75 was covalently bound to phenylalanyl-tRNA synthetase from Thermus thermophilus, and all criteria of an affinity modification were met. The main products of modification displaying various electrophoretic mobilities were formed by binding tRNAPhe-s4U-75 to the beta-subunit (major) of the enzyme. These data suggest that the nucleotide found at position 75 of tRNAPhe interacts with the beta-subunit of phenylalanyl-tRNA synthetase.

The tRNA(guanine-26,N2-N2) methyltransferase (Trm1) from the hyperthermophilic archaeon Pyrococcus furiosus: cloning, sequencing of the gene and its expression in Escherichia coli

The structural gene pfTRM1 (GenBank accession no. AF051912), encoding tRNA(guanine-26, N 2- N 2) methyltransferase (EC 2.1.1.32) of the strictly anaerobic hyperthermophilic archaeon Pyrococcus furiosus, has been identified by sequence similarity to the TRM1 gene of Saccharomyces cerevisiae (YDR120c). The pfTRM1 gene in a 3.0 kb restriction DNA fragment of P.furiosus genomic DNA has been cloned by library screening using a PCR probe to the 5'-part of the corresponding ORF. Sequence analysis revealed an entire ORF of 1143 bp encoding a polypeptide of 381 residues (calculated molecular mass 43.3 kDa). The deduced amino acid sequence of this newly identified gene shares significant similarity with the TRM1- like genes of three other archaea (Methanococcus jannaschii, Methanobacterium thermoautotrophicum and Archaeoglobus fulgidus), one eukaryon (Caenorhabditis elegans) and one hyperthermophilic eubacterium (Aquifex aeolicus). Two short consensus motifs for S-adenosyl-l-methionine binding are detected in the sequence of pfTrm1p. Cloning of the P.furiosus TRM1 gene in an Escherichia coli expression vector allowed expression of the recombinant protein (pfTrm1p) with an apparent molecular mass of 42 kDa. A protein extract from the transformed E.coli cells shows enzymatic activity for the quantitative formation of N 2, N 2-dimethylguanosine at position 26 in a transcript of yeast tRNAPhe used as substrate. The recombinant enzyme was also shown to modify bulk E.coli tRNAs in vivo.

Recognition of the 5' leader and the acceptor stem of a pre-tRNA substrate by the ribozyme from Bacillus subtilis RNase P

The catalysis by the ribozyme from bacterial RNase P involves specific interactions with the structure of the tRNA substrate. Recognition of the T stem-loop by this ribozyme occurs in a groove-like structure dictated by the tertiary folding of tRNA [Loria, A., and Pan, T. (1997) Biochemistry 36, 6317]. Effects of 2'-OH --> 2'-H modifications within the acceptor stem and the 5' leader on substrate binding and catalysis are determined using a tRNAPhe substrate that is significantly cleaved at more than one site. In all but one case, the 2'-deoxy substitution has little effect on binding for cleavage at the correct and incorrect sites. Substitution of the 2'-OH group at the correct site, however, decreases the cleavage chemistry by more than 3.4 kcal/mol for cleavage at both the correct and incorrect sites. Substitutions of the 2'-OH groups at the incorrect sites have no effect for cleavage at the incorrect and correct sites. Truncation of the 5' leader results in differential effects on cleavage at different sites. These observations lead to a model in which cleavage at the correct and incorrect sites involves formation of different ribozyme-substrate complexes depending on binding of specific nucleotides in the 5' leader. Binding of the T stem-loop of tRNA and the 2'-OH group at the correct cleavage site is common for all ES complexes. An A/U-rich 5' leader significantly promotes formation of the ES complex and accelerates the cleavage chemistry over those of a C/G-rich 5' leader, but only moderately enhances cleavage at the correct site over cleavage at the incorrect sites. Since cleavage at different sites requires formation of different ES complexes, cleavage site selection can occur at the level of the ES complex and at the chemical step.

A novel mitochondrial tRNA(Phe) mutation inhibiting anticodon stem formation associated with a muscle disease

We have identified a novel mitochondrial (mt) DNA mutation in the tRNA(Phe)-gene in a patient with an isolated mitochondrial myopathy. This T to C transition at position 618 disrupts a strictly conserved base pair within the anticodon stem of tRNA(Phe). Computer analysis showed that the affected base pair is essential for anticodon stem formation of tRNA(Phe). The mutant mtDNA was heteroplasmic in skeletal muscle (95% mutant) and peripheral blood cells (20% mutant) from the patient but was undetectable in blood cells from his healthy sister. The patient presented with ragged red fibers and reduced activities of complex I and complex III in skeletal muscle. The T618C mutation described here is the second found in this region. Both mutations affect the same base pair of the tRNA(Phe) anticodon stem substantiating the pathogenic nature of both mutations.

Recognition of the universally conserved 3'-CCA end of tRNA by elongation factor EF-Tu

Escherichia coli tRNA(Val) with pyrimidine substitutions for the universally conserved 3'-terminal adenine can be readily aminoacylated. It cannot, however, transfer valine into polypeptides. Conversely, despite being a poor substrate for valyl-tRNA synthetase, tRNA(Val) with a 3'-terminal guanine is active in in vitro polypeptide synthesis. To better understand the function of the 3'-CCA sequence of tRNA in protein synthesis, the effects of systematically varying all three bases on formation of the Val-tRNA(Val):EF-Tu:GTP ternary complex were investigated. Substitutions at C74 and C75 have no significant effect, but replacing A76 with pyrimidines decreases the affinity of valyl-tRNA(Val) for EF-Tu:GTP, thus explaining the inability of these tRNA(Val) variants to function in polypeptide synthesis. Valyl-tRNA(Val) terminating in 3'-guanine is readily recognized by EF-TU:GTP. Dissociation constants of the EF-Tu:GTP ternary complexes with valine tRNAs having nucleotide substitutions at the 3' end increase in the order adenine < guanine < uracil; EF-Tu has very little affinity for tRNA terminating in 3' cytosine. Similar observations were made in studies of the interaction of 3' end mutants of E. coli tRNA(Ala) and tRNA(Phe) with EF-Tu:GTP. These results indicate that EF-Tu:GTP preferentially recognizes purines and discriminates against pyrimidines, especially cytosine, at the 3' end of aminoacyl-tRNAs.

Preparation of active tRNA gene transcripts devoid of 3'-extended products and dimers

Significant amounts (10-30%) of 3'-extended products with one or two extra nucleotides are synthesized in the course of run-off tRNA gene transcription with T7 RNA polymerase. Denaturing polyacrylamide gel electrophoresis appeared to be insufficient to provide preparative amounts of pure correct-size transcripts. Formation of dimers by tRNA gene transcripts as side products in the course of their activation is also another obstacle in preparation of biologically active transcripts. Here, we have shown that EF-Tu affinity chromatography and/or non-denaturing electrophoresis are simple and efficient tools for isolation of highly active correct-size transcripts. Conditions for transcript activation in vitro should be carefully controlled to prevent dimer formation and obtain reliable data on tRNA transcript structure and function.

Evolution of rhizobia by acquisition of a 500-kb symbiosis island that integrates into a phe-tRNA gene

Nodulation and nitrogen fixation genes of Mesorhizobium loti are encoded on the chromosome of the bacterium. Nevertheless, there is strong evidence that these genes can be transferred from an inoculant strain to nonsymbiotic mesorhizobia in the field environment. Here we report that the chromosomal symbiotic element of M. loti strain ICMP3153 is transmissible in laboratory matings to at least three genomic species of nonsymbiotic mesorhizobia. The element is 500 kb in size, integrates into a phe-tRNA gene, and encodes an integrase of the phage P4 family just within its left end. The entire phe-tRNA gene is reconstructed at the left end of the element upon integration, whereas the 3' 17 nucleotides of the tRNA gene are present as a direct repeat at the right end. We termed the element a symbiosis island on the basis of its many similarities to pathogenicity islands. It may represent a class of genetic element that contributes to microbial evolution by acquisition.

Ribosome-catalyzed peptide-bond formation with an A-site substrate covalently linked to 23S ribosomal RNA

In the ribosome, the aminoacyl-transfer RNA (tRNA) analog 4-thio-dT-p-C-p-puromycin crosslinks photochemically with G2553 of 23S ribosomal RNA (rRNA). This covalently linked substrate reacts with a peptidyl-tRNA analog to form a peptide bond in a peptidyl transferase-catalyzed reaction. This result places the conserved 2555 loop of 23S rRNA at the peptidyl transferase A site and suggests that peptide bond formation can occur uncoupled from movement of the A-site tRNA. Crosslink formation depends on occupancy of the P site by a tRNA carrying an intact CCA acceptor end, indicating that peptidyl-tRNA, directly or indirectly, helps to create the peptidyl transferase A site.

A liquid chromatography/electrospray mass spectrometric study on the post-transcriptional modification of tRNA

Liquid chromatography/electrospray mass spectrometry is one of the rapidly developing techniques with which mass of large hydrophilic polymers such as proteins and nucleic acids can be determined precisely. The technique was applied to studies on the modifications of tRNAs. Various tRNA species purified from Escherichia coli were directly injected into a capillary reversed-phase column and the desalted and concentrated tRNAs were analyzed on-line with an electrospray mass spectrometer. In some cases, small but significant differences were noted between the theoretical and observed molecular masses, suggesting that there exist still unknown modifications. Under high resolution measurements, multiple peaks corresponding to species modified to a varying extent were resolved. To study the structures in detail, the isolated tRNA species were digested with ribonuclease T1, and the resulting mixture of fragments were analyzed by the same liquid chromatography/mass spectrometry. In this way, most of the fragments were easily identified solely from their masses, and the positions where the expected and real structures differ were revealed. The results obtained showed the presence of micro-heterogeneity among tRNAs and demonstrated at the same time the power of the hyphenated technique for the structural analysis on nucleic acids.

Probing structural elements in RNA using engineered disulfide cross-links

Three analogs of unmodified yeast tRNAPhe, each possessing a single disulfide cross-link, have been designed and synthesized. One cross-link is between G1 and C72 in the amino acid acceptor stem, a second cross-link is in the central D region of yeast tRNAPhe between C11 and C25 and the third cross-link bridges U16 and C60 at the D loop/T loop interface. Air oxidation to form the cross-links is quantitative and analysis of the cross-linked products by native and denaturing PAGE, RNase T1 mapping, Pb(II) cleavage, UV cross-linking and thermal denaturation demonstrates that the disulfide bridges do not alter folding of the modified tRNAs relative to the parent sequence. The finding that cross-link formation between thiol-derivatized residues correlates with the position of these groups in the crystal structure of native yeast tRNAPhe and that the modifications do not significantly perturb native structure suggests that this methodology should be applicable to the study of RNA structure, conformational dynamics and folding pathways.

Phylogenetic analysis of chloroplast DNA variation in Coffea L

The trnL-trnF intergenic spacer of cpDNA has been sequenced from 38 tree samples representing 23 Coffea taxa and the related genus Psilanthus. These sequences were used for phylogenetic reconstruction using parsimony analyses. The results suggest a radial mode of speciation and a recent origin in Africa for the genus Coffea. Phylogenetic relationships inferred from the cpDNA analysis suggest several major clades, which present a strong geographical correspondence (i.e., west Africa, central Africa, east Africa, and Madagascar). The overall results agree well with the phylogeny previously inferred from nuclear genome data. However, several inconsistencies are observed among taxa endemic to west Africa, suggesting the occurrence of introgressive hybridization. Evidence is also obtained for the genetic origin of the allotetraploid species C. arabica.