Identification of the mass-silent post-transcriptionally modified nucleoside pseudouridine in RNA by matrix-assisted laser desorption/ionization mass spectrometry

A new method using matrix-assisted laser desorption/ionization (MALDI) mass spectrometry for the direct analysis of the mass-silent post-transcriptionally modified nucleoside pseudouridine in nucleic acids has been developed. This method utilizes 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide to derivatize pseudouridine residues. After chemical derivatization all pseudouridine residues will contain a 252 Da 'mass tag' that allows the presence of pseudouridine to be identified using mass spectrometry. Pseudouridine residues can be identified in intact nucleic acids by obtaining a mass spectrum of the nucleic acid before and after derivatization. The mass difference (in units of 252 Da) will denote the number of pseudouridine residues present. To determine the sequence location of pseudouridine, a combination of enzymatic hydrolysis and mass spectrometric steps are used. Here, MALDI analysis of RNase T1 digestion products before and after modification are used to narrow the sequence location of pseudouridine to specific T1 fragments in the gene sequence. Further mass spectrometric monitoring of exonuclease digestion products from isolated T1 fragments is then used for exact sequence placement. This approach to pseudouridine identification is demonstrated using Escherichia coli tRNAS: This new method allows for the direct determination of pseudouridine in nucleic acids, can be used to identify modified pseudouridine residues and can be used with general modification mapping approaches to completely characterize the post-transcriptional modifications present in RNAs.

Tubulointerstitial nephritis associated with a novel mitochondrial point mutation

BACKGROUND

Nephropathy caused by mitochondrial disorders is a relatively newly recognized disease. Only a few cases have been reported in the literature, and most of them are proximal tubulopathy-presenting Fanconi syndrome. Here we report on a novel mutation in two familial cases of tubulointerstitial nephropathy associated with concentrating defect.

METHODS

Renal biopsy specimens were examined by light microscopy and electron microscopy. Mitochondrial genomic DNA isolated from renal biopsy specimens was amplified by polymerase chain reaction (PCR) and sequenced in its entirety. The DNA sequences were analyzed by (1) comparing with the Anderson et al's mitochondrial sequences; (2) comparing with DNA sequences obtained from 97 human controls, including both healthy individuals and patients with renal diseases; and (3) comparing with the counterparts in 90 different species.

RESULTS

Dismorphic mitochondria with occasional intramitochondrial inclusions were found in the renal tubular epithelial cells. A novel mitochondrial point mutation was identified at the position 608, that is, the distal end of the anticodon stem of the tRNA(Phe) molecule. The A to G substitution at this position was not observed in 97 human controls and was found to be highly conserved in evolution.

CONCLUSIONS

We have identified an A608G mutation of mitochondrial genome in two cases whose presentation include tubulointerstitial nephritis and stroke.

Altered mitochondrial gene expression in human gestational trophoblastic diseases

To assess the molecular basis of phenotypic alterations present in the gestational trophoblastic diseases (GTDs) and to identify genes whose expression is specifically associated with these placental proliferative disorders we performed differential display (DD) techniques. This strategy resulted in the isolation of four mitochondrial transcripts downregulated in benign, as well as in malignant, trophoblastic diseases encoding the cytochrome oxidase subunit I (COX I), the ATPase subunit 6, the 12S ribosomal RNA (12S rRNA) and the transfer RNA for phenylalanine (tRNA(Phe)). This expression pattern was confirmed by Northern blot in normal early placenta (NEP), complete hydatidiform mole (CHM), persistent gestational trophoblastic disease (PGTD) and the human choriocarcinoma derived cell line JEG-3. Quantification of mitochondrial DNA by dot blot indicated that these changes in expression were not associated with a significant alteration in the number of mitochondrial genome. In addition, a reduction in the mitochondrial transcription factor A (mtTFA) mRNA level was observed in benign as well as in malignant trophoblastic diseases in correlation with the decrease in the mitochondrial transcript levels. Furthermore, Western blot analysis for COX-I showed a close parallelism with the expression level of the cognate RNA. Taken together, these data demonstrate that a significant change in mitochondrial transcription is associated with the phenotypic alteration present in GTDs.

afa-8 Gene cluster is carried by a pathogenicity island inserted into the tRNA(Phe) of human and bovine pathogenic Escherichia coli isolates

We recently described a new afimbrial adhesin, AfaE-VIII, produced by animal strains associated with diarrhea and septicemia and by human isolates associated with extraintestinal infections. Here, we report that the afa-8 operon, encoding AfaE-VIII adhesin, from the human blood isolate Escherichia coli AL862 is carried by a 61-kb genomic region with characteristics typical of a pathogenicity island (PAI), including a size larger than 10 kb, the presence of an integrase-encoding gene, the insertion into a tRNA locus (pheR), and the presence of a small direct repeat at each extremity. Moreover, the G+C content of the afa-8 operon (46.4%) is lower than that of the E. coli K-12/MG1655 chromosome (50.8%). Within this PAI, designated PAI I(AL862), we identified open reading frames able to code for products similar to proteins involved in sugar utilization. Four probes spanning these sequences hybridized with 74.3% of pathogenic afa-8-positive E. coli strains isolated from humans and animals, 25% of human pathogenic afa-8-negative E. coli strains, and only 8% of fecal strains (P = 0.05), indicating that these sequences are strongly associated with the afa-8 operon and that this genetic association may define a PAI widely distributed among human and animal afa-8-positive strains. One of the distinctive features of this study is that E. coli AL862 also carries another afa-8-containing PAI (PAI II(AL862)), which appeared to be similar in size and genetic organization to PAI I(AL862) and was inserted into the pheV gene. We investigated the insertion sites of afa-8-containing PAI in human and bovine pathogenic E. coli strains and found that this PAI preferentially inserted into the pheV gene.

1-Methylguanosine in place of Y base at position 37 in phenylalanine tRNA is responsible for its shiftiness in retroviral ribosomal frameshifting

Many mammalian retroviruses express their protease and polymerase by ribosomal frameshifting. It was originally proposed that a specialized shifty tRNA promotes the frameshift event. We previously observed that phenylalanine tRNA(Phe) lacking the highly modified wybutoxosine (Y) base on the 3' side of its anticodon stimulated frameshifting, demonstrating that this tRNA is shifty. We now report the shifty tRNA(Phe) contains 1-methylguanosine (m(1)G) in place of Y and that the m(1)G form from rabbit reticulocytes stimulates frameshifting more efficiently than its m(1)G-containing counterpart from mouse neuroblastoma cells. The latter tRNA contains unmodified C and G nucleosides at positions 32 and 34, respectively, while the former tRNA contains the analogous 2'-O-methylated nucleosides at these positions. The data suggest that not only does the loss of a highly modified base from the 3' side of the anticodon render tRNA(Phe) shifty, but the modification status of the entire anticodon loop contributes to the degree of shiftiness. Possible biological consequences of these findings are discussed.

Essential regions of the tRNA primer required for HIV-1 infectivity

Human immunodeficiency virus (HIV), like all retroviruses, requires a cellular tRNA as a primer for initiation of reverse transcription. In a previous study, we demonstrated that an HIV-1 with a primer binding site complementary to yeast tRNA(Phe) (psHIV-Phe) was not infectious unless yeast tRNA(Phe) was supplied in trans. This unique in vivo complementation system has now been used to define the elements of the tRNA required for HIV-1 replication. Mutant tRNA(Phe) with deletions in TPsiC stem-loop, anticodon stem-loop or D stem-loop of the tRNA were generated and assessed for the capacity to rescue psHIV-Phe. Mutant tRNA(Phe) with disrupted TPsiC stem-loop did not rescue psHIV-Phe. In contrast, a mutant tRNA(Phe) without the D stem-loop was fully functional for the rescue. The tRNA anticodon stem-loop region was found to be important for efficient complementation. The results of our studies demonstrate for the first time the importance of specific structural and sequence elements of the tRNA primer for HIV-1 reverse transcription and define new targets for interruption of HIV-1 replication.

Molecular dynamics of the anticodon domain of yeast tRNA(Phe): codon-anticodon interaction

We have studied the effect of codon-anticodon interaction on the structure and dynamics of transfer RNAs using molecular dynamics simulations over a nanosecond time scale. From our molecular dynamical investigations of the solvated anticodon domain of yeast tRNA(Phe) in the presence and absence of the codon trinucleotides UUC and UUU, we find that, although at a gross level the structures are quite similar for the free and the bound domains, there are small but distinct differences in certain parts of the molecule, notably near the Y37 base. Comparison of the dynamics in terms of interatomic or inter-residual distance fluctuation for the free and the bound domains showed regions of enhanced rigidity in the loop region in the presence of codons. Because fluorescence experiments suggested the existence of multiple conformers of the anticodon domain, which interconvert on a much larger time scale than our simulations, we probed the conformational space using five independent trajectories of 500 ps duration. A generalized ergodic measure analysis of the trajectories revealed that at least for this time scale, all the trajectories populated separate parts of the conformational space, indicating a need for even longer simulations or enhanced sampling of the conformational space to give an unequivocal answer to this question.

Energetic contribution of tRNA hybrid state formation to translocation catalysis on the ribosome

Upon transpeptidylation, the 3' end of aminoacyl-tRNA (aa-tRNA) in the ribosomal A site enters the A/P hybrid state. We report that transpeptidylation of Phe-tRNA to fMetPhe-tRNA on Escherichia coli ribosomes substantially lowers the kinetic stability of the ribosome-tRNA complex and decreases the affinity by 18.9 kJ mol(-1). At the same time, the free energy of activation of elongation factor G dependent translocation decreases by 12.5 kJ mol(-1), indicating that part of the free energy of transpeptidylation is used to drive translocation kinetically. Thus, the formation of the A/P hybrid state constitutes an important element of the translocation mechanism.

The 3' substrate determinants for the catalytic efficiency of the Bacillus subtilis RNase P holoenzyme suggest autolytic processing of the RNase P RNA in vivo

We investigated the catalytic efficiency and the specificity of the Bacillus subtilis RNase P holoenzyme reaction with substrates that contain a single strand, a hairpin loop, or a tRNA 3' to the cleavage site. At a saturating ribozyme concentration, RNase P can cleave a single-stranded RNA at approximately 0.6 min(-1) at pH 7.8. Replacing the single-stranded RNA 3' to the cleavage site by a hairpin loop or by the yeast tRNA(Phe) increases the cleavage rate by up to approximately 600-fold and approximately 3,200-fold, respectively. These results show that compared to a single-stranded RNA substrate, the cleavage rate for the holoenzyme reaction is primarily enhanced by an acceptor-stem-like helix. Substrate binding, approximately 7-10 microM for a single-stranded RNA, improves by approximately 1,000-fold upon the addition of the tRNA. The efficiency of the RNase P holoenzyme cleaving a single-stranded RNA is sufficiently high to consider autolytic processing of the RNase P RNA (denoted P RNA) transcript in the cell. The addition of the RNase P protein to a precursor form of the P RNA in vitro results in autolytic processing of the 5' and the 3' end of this precursor in a matter of minutes. Autolytic processing produces the reported 5' end of the mature P RNA. The precise 3' end generated by autolytic processing is different over the course of the reaction and the final product is 4 nt shorter than the reported 3' end of the B. subtilis P RNA. The observed 3' end in vitro is consistent with the property of the holoenzyme reaction with single-stranded RNA substrates. The discrepancy with the reported 3' end may be due to other processing events in vivo or inaccurate determination of the mature 3' end of the P RNA isolated from the cell. We propose that the mature B. subtilis P RNA is generated at least in part by autolytic processing upon the binding of the RNase P protein to the precursor P RNA.

Patterns of nucleotide substitution in angiosperm cpDNA trnL (UAA)-trnF (GAA) regions

Patterns of substitution in chloroplast encoded trnL_F regions were compared between species of Actaea (Ranunculales), Digitalis (Scrophulariales), Drosera (Caryophyllales), Panicoideae (Poales), the small chromosome species clade of Pelargonium (Geraniales), each representing a different order of flowering plants, and Huperzia (Lycopodiales). In total, the study included 265 taxa, each with > 900-bp sequences, totaling 0.24 Mb. Both pairwise and phylogeny-based comparisons were used to assess nucleotide substitution patterns. In all six groups, we found that transition/transversion ratios, as estimated by maximum likelihood on most-parsimonious trees, ranged between 0.8 and 1.0 for ingroups. These values occurred both at low sequence divergences, where substitutional saturation, i.e., multiple substitutions having occurred at the same (homologous) nucleotide position, was not expected, and at higher levels of divergence. This suggests that the angiosperm trnL-F regions evolve in a pattern different from that generally observed for nuclear and animal mtDNA (transitional/transversion ratio > or = 2). Transition/transversion ratios in the intron and the spacer region differed in all alignments compared, yet base compositions between the regions were highly similar in all six groups. A>-<T and G<->C transversions were significantly less frequent than the other four substitution types. This correlates with results from studies on fidelity mechanisms in DNA replication that predict A<->T and G<->C transversions to be least likely to occur. It therefore strengthens confidence in the link between mutation bias at the polymerase level and the actual fixation of substitutions as recorded on evolutionary trees, and concomitantly, in the neutrality of nucleotide substitutions as phylogenetic markers.

Evaluation of uranyl photocleavage as a probe to monitor ion binding and flexibility in RNAs

In order to evaluate uranyl photocleavage as a tool to identify and characterize structural and dynamic properties in RNA, we compared uranyl cleavage sites in five RNA molecules with known X-ray structures, namely the hammerhead and hepatitis delta virus ribozymes, the P4-P6 domain of the Tetrahymena group I intron, as well as tRNA(Phe) and tRNA(Asp) from yeast. Uranyl photocleavage was observed at specific positions in all molecules investigated. In order to characterize the sites, photocleavage was performed in the absence and in increasing amounts of MgCl(2). Uranyl photocleavage correlates well with sites of low calculated accessibility, suggesting that uranyl ions bind in tight RNA pockets formed by close approach of phosphate groups. RNA foldings require ion binding, usually magnesium ions. Thus, upon the adoption of the native structure, uranyl ions can no longer bind well except in flexible and open to the solvent regions that can undergo induced-fit without disrupting the native fold. Uranyl photocleavage was compared to N-ethyl-N-nitrosourea and lead-induced cleavages in the context of the three-dimensional X-ray structures. Overall, the regions protected from ENU attack are sites of uranyl cleavage, indicating sites of low accessibility which can form ion binding sites. On the contrary, lead cleavages occur at flexible and accessible sites and correlate with the unspecific cleavages prevalent in dynamic and open regions. Applied in a magnesium-dependent manner, and only in combination with other backbone probing agents such as N-ethyl-N-nitrosourea, lead and Fenton cleavage, uranyl probing has the potential to reveal high-affinity metal ion environments, as well as regions involved in conformational transitions.

Phylogenetic relationships of the North American sturgeons (order Acipenseriformes) based on mitochondrial DNA sequences

The evolutionary relationships of the extant species within the order Acipenseriformes are not well understood. Nucleotide sequences of four mitochondrial genes (12S rRNA, COII, tRNA(Phe), and tRNA(Asp) genes) in North American sturgeon and paddlefish were examined to reconstruct a phylogeny. Analysis of the combined gene sequences suggests a basal placement of the paddlefish with regard to the sturgeons. Nucleotide sequences of all four genes for the three Scaphirhynchus species were identical. The position of Scaphirhynchus based on our data was uncertain. Within the genus Acipenser, the two Acipenser oxyrinchus subspecies were very similar in sequence and found to be basal to the remaining Acipenser species examined. Based on our data, Acipenser transmontanus and Acipenser medirostris were sister taxa, as were Acipenser fulvescens and Acipenser brevirostrum. Comparison of our results with hypotheses of sturgeon relationships proposed by previous authors is presented. The sequence data presented here are phylogenetically useful and provide a solid foundation of genetic information for the North American Acipenseriformes that can be expanded to include Eurasian species to provide a global picture of sturgeon evolution.

Periodic conformational changes in rRNA: monitoring the dynamics of translating ribosomes

In protein synthesis, a tRNA transits the ribosome via consecutive binding to the A (acceptor), P (peptidyl), and E (exit) site; these tRNA movements are catalyzed by elongation factor G (EF-G) and GTP. Site-specific Pb2+ cleavage was applied to trace tertiary alterations in tRNA and all rRNAs on pre- and posttranslocational ribosomes. The cleavage pattern of deacylated tRNA and AcPhe-tRNA changed individually upon binding to the ribosome; however, these different conformations were unaffected by translocation. On the other hand, translocation affects 23S rRNA structure. Significantly, the Pb2+ cleavage pattern near the peptidyl transferase center was different before and after translocation. This structural rearrangement emerged periodically during elongation, thus providing evidence for a dynamic and mobile role of 23S rRNA in translocation.

Mg(2+) binding to tRNA revisited: the nonlinear Poisson-Boltzmann model

Our current understanding of Mg(2+) binding to RNA, in both thermodynamic and structural terms, is largely based on classical studies of transfer RNAs. Based on these studies, it is clear that magnesium ions are crucial for stabilizing the folded structure of tRNA. We present here a rigorous theoretical model based on the nonlinear Poisson-Boltzmann (NLPB) equation for understanding Mg(2+) binding to yeast tRNA(Phe). We use this model to interpret a variety of experimental Mg(2+) binding data. In particular, we find that the NLPB equation provides a remarkably accurate description of both the overall stoichiometry and the free energy of Mg(2+) binding to yeast tRNA(Phe) without any fitted parameters. In addition, the model accurately describes the interaction of Mg(2+) with localized regions of the RNA as determined by the pK(a) shift of differently bound fluorophores. In each case, we find that the model also reproduces the univalent salt-dependence and the anticooperativity of Mg(2+) binding. Our results lead us to a thermodynamic description of Mg(2+) binding to yeast tRNA(Phe) based on the NLPB equation. In this model, Mg(2+) binding is simply explained by an ensemble of ions distributed according to a Boltzmann weighted average of the mean electrostatic potential around the RNA. It appears that the entire ensemble of electrostatically bound ions superficially mimics a few strongly coordinated ions. In this regard, we find that Mg(2+) stabilizes the tertiary structure of yeast tRNA(Phe) in part by accumulating in regions of high negative electrostatic potential. These regions of Mg(2+) localization correspond to bound ions that are observed in the X-ray crystallographic structures of yeast tRNA(Phe). Based on our results and the available thermodynamic data, there is no evidence that specifically coordinated Mg ions have a significant role in stabilizing the native tertiary structure of yeast tRNA(Phe) in solution.

Evolution and phylogenetic information content of mitochondrial genomic structural features illustrated with acrodont lizards

DNA sequences from 195 squamate reptiles indicate that mitochondrial gene order is the most reliable phylogenetic character establishing monophyly of acrodont lizards and of the snake families Boidae, Colubridae, and Viperidae. Gene order shows no evidence of evolutionary parallelisms or reversals in these taxa. Derived secondary structures of mitochondrial tRNAs also prove to be useful phylogenetic characters showing no reversals. Parallelisms for secondary structures of tRNAs are restricted to deep lineages that are separated by at least 200 million years of independent evolution. Presence of a stem-and-loop structure between the genes encoding tRNA(Asn) and tRNA(Cys), where the replication origin for light-strand synthesis is typically located in vertebrate mitochondrial genomes, is found to undergo at least three and possibly as many as seven evolutionary shifts, most likely parallel losses. This character is therefore a less desirable phylogenetic marker than the other structural changes examined. Sequencing regions that contain multiple genes, including tRNA genes, may be preferable to the common practice of obtaining single-gene fragments for phylogenetic inference because it permits observation of major structural changes in the mitochondrial genome. Such characters may occasionally provide phylogenetic information on relatively short internal branches for which base substitutional changes are expected to be relatively uninformative.

Repair of tRNAs in metazoan mitochondria

The integrity of 3'-ends of tRNAs is essential for aminoacylation and consequently for protein synthesis. The CCA-termini are generated and, if truncated by exonucleolytic activity, restored by tRNA nucleotidyltransferase. However, further truncations at the 3'-end can occur by exonuclease activity or during processing of overlapping tRNA primary transcripts in metazoan mitochondria. In the latter case, the upstream tRNA is released in a 3'-truncated form (lacking up to six bases) and subsequently completed. In human mitochondria, tRNA(Tyr)(missing the discriminator nucleotide A(73)) is completed by a discriminator adding activity followed by CCA addition. Since in vivo a high percentage of further 3'-terminally degraded human tRNA(Tyr)transcripts could be observed, it was tested in an in vitro system whether this repair mechanism for tRNA 3'-ends acts also on these further degraded tRNA versions. Additionally, 3'-truncated versions of two non-overlapping mitochondrial tRNAs (tRNA(Thr)and tRNA(Phe)) were examined. The results show that these transcripts can be repaired during incubation. A similar base incorporating activity was observed in mouse mitochondria, indicating that a repair mechanism for the 3'-end of several tRNAs exists in mitochondria of humans and possibly other metazoans which goes beyond the CCA addition.

Late events of translation initiation in bacteria: a kinetic analysis

Binding of the 50S ribosomal subunit to the 30S initiation complex and the subsequent transition from the initiation to the elongation phase up to the synthesis of the first peptide bond represent crucial steps in the translation pathway. The reactions that characterize these transitions were analyzed by quench-flow and fluorescence stopped-flow kinetic techniques. IF2-dependent GTP hydrolysis was fast (30/s) followed by slow P(i) release from the complex (1.5/s). The latter step was rate limiting for subsequent A-site binding of EF-Tu small middle dotGTP small middle dotPhe-tRNA(Phe) ternary complex. Most of the elemental rate constants of A-site binding were similar to those measured on poly(U), with the notable exception of the formation of the first peptide bond which occurred at a rate of 0.2/s. Omission of GTP or its replacement with GDP had no effect, indicating that neither the adjustment of fMet-tRNA(fMet) in the P site nor the release of IF2 from the ribosome required GTP hydrolysis.

Sense codon-dependent introduction of unnatural amino acids into multiple sites of a protein

Cell-free protein synthesis, driven by a crude S30 extract from Escherichia coli, has been applied to the preparation of proteins containing unnatural amino acids at specific positions. We have developed methods for inactivating tRNA(Asp) and tRNA(Phe) within a crude E. coli tRNA by an antisense treatment and for digesting most of the tRNA within the S30 extract without essential damage to the ribosomal activity. In the present study, we applied these methods to the substitution of Asp and Phe residues of the HIV-1 protease with unnatural amino acids. With 10 mM Mg(2+), the translation efficiency was higher than that with the other tested concentration, and the misreading efficiency was low. The protease mRNA was translated in the presence of an antisense DNA-treated tRNA mixture and 2-naphthylalanyl- and/or p-phenylazophenylalanyl-tRNA. The results suggest that a good portion of the translation products are substituted at all of the seven positions originally occupied by Asp or Phe.

Evidence for an RNA-based catalytic mechanism in eukaryotic nuclear ribonuclease P

Ribonuclease P is the enzyme responsible for removing the 5'-leader segment of precursor transfer RNAs in all organisms. All eukaryotic nuclear RNase Ps are ribonucleoproteins in which multiple protein components and a single RNA species are required for activity in vitro as well as in vivo. It is not known, however, which subunits participate directly in phosphodiester-bond hydrolysis. The RNA subunit of nuclear RNase P is evolutionarily related to its catalytically active bacterial counterpart, prompting speculation that in eukaryotes the RNA may be the catalytic component. In the bacterial RNase P reaction, Mg(II) is required to coordinate the nonbridging phosphodiester oxygen(s) of the scissile bond. As a consequence, bacterial RNase P cannot cleave pre-tRNA in which the pro-Rp nonbridging oxygen of the scissile bond is replaced by sulfur. In contrast, the RNase P reaction in plant chloroplasts is catalyzed by a protein enzyme whose mechanism does not involve Mg(II) coordinated by the pro-Rp oxygen. To determine whether the mechanism of nuclear RNase P resembles more closely an RNA- or a protein-catalyzed reaction, we analyzed the ability of Saccharomyces cerevisiae nuclear RNase P to cleave pre-tRNA containing a sulfur substitution of the pro-Rp oxygen at the cleavage site. Sulfur substitution at this position prohibits correct cleavage of pre-tRNA. Cleavage by eukaryotic RNase P thus depends on the presence of a thio-sensitive ligand to the pro-Rp oxygen of the scissile bond, and is consistent with a common, RNA-based mechanism for the bacterial and eukaryal enzymes.

Chloroplast ribonuclease P does not utilize the ribozyme-type pre-tRNA cleavage mechanism

The transfer RNA 5' maturation enzyme RNase P has been characterized in Bacteria, Archaea, and Eukarya. The purified enzyme from all three kingdoms is a ribonucleoprotein containing an essential RNA subunit; indeed, the RNA subunit of bacterial RNase P RNA is the sole catalytic component. In contrast, the RNase P activity isolated from spinach chloroplasts lacks an RNA component and appears to function as a catalytic protein. Nonetheless, the chloroplast enzyme recognizes a pre-tRNA substrate for E. coli RNase P and cleaves it as efficiently and precisely as does the bacterial enzyme. To ascertain whether there are differences in catalytic mechanism between an all-RNA and an all-protein RNase P, we took advantage of the fact that phosphodiester bond selection and hydrolysis by the E. coli RNase P ribozyme is directed by a Mg2+ ion coordinated to the nonbridging pro-Rp oxygen of the scissile bond, and is blocked by sulfur replacement of this oxygen. We therefore tested the ability of the chloroplast enzyme to process a precursor tRNA containing this sulfur substitution. Partially purified RNase P from spinach chloroplasts can accurately and efficiently process phosphorothioate-substituted pre-tRNAs; cleavage occurs exclusively at the thio-containing scissile bond. The enzymatic throughput is fivefold slower, consistent with a general chemical effect of the phosphorothioate substitution rather than with a metal coordination deficiency. The chloroplast RNase P reaction mechanism therefore does not involve a catalytic Mg2+ bonded to the pro-Rp phosphate oxygen, and hence is distinct from the mechanism of the bacterial ribozyme RNase P.

Modified constructs of the tRNA TPsiC domain to probe substrate conformational requirements of m(1)A(58) and m(5)U(54) tRNA methyltransferases

The TPsiC stem and loop (TSL) of tRNA contains highly conserved nucleoside modifications, m(5)C(49), T(54), Psi(55)and m(1)A(58). U(54)is methylated to m(5)U (T) by m(5)U(54)methyltransferase (RUMT); A(58)is methylated to m(1)A by m(1)A(58)tRNA methyltransferase (RAMT). RUMT recognizes and methylates a minimal TSL heptadecamer and RAMT has previously been reported to recognize and methylate the 3'-half of the tRNA molecule. We report that RAMT can recognize and methylate a TSL heptadecamer. To better understand the sensitivity of RAMT and RUMT to TSL conformation, we have designed and synthesized variously modified TSL constructs with altered local conformations and stabilities. TSLs were synthesized with natural modifications (T(54)and Psi(55)), naturally occurring modifications at unnatural positions (m(5)C(60)), altered sugar puckers (dU(54)and/or dU(55)) or with disrupted U-turn interactions (m(1)Psi(55)or m(1)m(3)Psi(55)). The unmodified heptadecamer TSL was a substrate of both RAMT and RUMT. The presence of T(54)increased thermal stability of the TSL and dramatically reduced RAMT activity toward the substrate. Local conformation around U(54)was found to be an important determinant for the activities of both RAMT and RUMT.

Transfer RNA identity change in anticodon variants of E. coli tRNA(Phe) in vivo

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

Effects of C5 protein on Escherichia coli RNase P catalysis with a precursor tRNA(Phe) bearing a single mismatch in the acceptor stem

Escherichia coli RNase P, an RNA-processing enzyme that cleaves precursor tRNAs to generate the mature 5'-end, is composed of a catalytic component (M1 RNA) and a protein cofactor (C5 protein). In this study, effects of C5 protein on the RNase P catalysis with a precursor E. coli tRNA(Phe) having a single mismatch in the acceptor stem were examined. This mutant precursor unexpectedly generated upstream cleavage products at the -8 position as well as normal cleavage products at the +1 position. The cleavage at the -8 position was essentially effective only in the presence of C5 protein. Possible secondary structures for cleavage at the -8 position deviate significantly from the structures of the known RNase P substrates, implying that C5 protein can allow the enzyme to broaden the substrate specificity more than previously appreciated.

Effects of terminal deletions in C5 protein on promoting RNase P catalysis

Deletion derivatives of C5 protein, the protein cofactor of Escherichia coli RNase P, were constructed as soluble MBP (maltose-binding protein) fusion proteins to assess the deletion effects on promoting RNase P catalysis and on binding to M1 RNA, the catalytic subunit of the enzyme. The C5 protein, with large terminal deletions, retained its promoting activity of RNase P catalysis under protein excess conditions in vitro. Some deletion derivatives complemented the temperature sensitive phenotype of E. coli A49 cells carrying the rnpA49 mutation. This ability also suggests that part of the C5 protein is enough to produce the catalytic activity of RNase P in vivo. Both the central conserved region, called the RNR motif, and the C-terminal region are essential for the binding of C5 protein to M1 RNA. Meanwhile, the N-terminal region contributes to promoting RNase P catalysis in ways other than binding to M1 RNA.