Characterization and selectivity of catalytic antibodies from human serum with RNase activity

IgG purified from sera of several patients with systemic lupus erythematosus and hepatitis B are shown to present RNA hydrolyzing activities that are different from the weak RNase A-type activities found in the sera of healthy donors. Further investigation brings evidence for two intrinsic activities, one observed in low salt conditions and another specifically stimulated by Mg2+ions and distinguishable from human sera RNases. Cleavage of RNA substrates by the latter activity is not sequence-specific but sensitive to both subtle conformational and/or drastic folding changes, as evidenced by comparative analysis of couples of structurally well-studied RNA substrates. These include yeast tRNAAsp and its in vitro transcript and human mitochondrial tRNALys-derived in vitro transcripts. The discovery of catalytic antibodies with RNase activities is a first step towards creation of a new generation of tools for the investigation of RNA structure.

Crystals of Thermus thermophilus tRNAAsp complexed with its cognate aspartyl-tRNA synthetase have a solvent content of 75%. Comparison with other aminoacylation systems

Thermus thermophilus tRNAAsp, purified from a non-recombinant source, has been crystallized in a complex with its cognate dimeric (alpha2) aspartyl-tRNA synthetase. Crystals diffract to 2.9 A resolution and belong to space group P63 with cell parameters a = b = 258, c = 90.9 A. The crystals contain one aspartyl-tRNA synthetase dimer and two tRNA molecules in the asymmetric unit, corresponding to a Vm of 4.85 A3 Da-1 and 75% solvent content. When compared with those obtained for globular proteins these values are high, but fall within the range observed for other aminoacyl-tRNA synthetases, either free or complexed with their tRNAs. A comparative survey is presented here.

Determination of 2'-hydroxyl and phosphate groups important for aminoacylation of Escherichia coli tRNAAsp: a nucleotide analogue interference study

2'-Deoxynucleoside 5'-a-thiotriphosphates have been incorporated randomly, replacing any of the four nucleotides separately and at a low level in Escherichia colitRNA(AsP)transcripts. After some tRNAs were charged with the cognate aminoacyl-tRNA synthetase and biotinylated, charged and uncharged tRNAs were separated by binding to Streptavidin. A comparison of the iodine cleavage pattern of charged and uncharged tRNAs indicated positions of 2'-deoxyphosphorothioate interference with charging. To separate the 2'-deoxy from the phosphorothioate effect, the same sequence of reactions was performed with the corresponding NTPalphaS. Several positions were identified with a 2'-deoxy or a phosphorothioate effect. tRNAs with single deoxy substitutions at the identified positions were prepared by enzymatic ligation of chemically synthesized halves. The kinetics of charging these tRNAs were determined. The 2'-deoxy effects identified by the interference assay were confirmed, showing a reduction in charging efficiency of between 2.5-6-fold, except for the terminal A76 with a 25-fold reduction. Inspection of the X-ray structure of the tRNA-synthetase complex showed consistency of most of these findings. Critical 2'-deoxy groups are localized mainly on the proposed contact surface with the synthetase or at the interface of the two tRNA domains. The same overall picture emerged for critical phosphorothioates. With the exception of 2'-deoxy-adenosine-containing tRNAs, multiple 2'-deoxy-substituted tRNAs, prepared by ligation of halves, showed a much larger reduction in charging efficiency than the mono-substituted tRNAs, indicating an additive effect.

Thermus thermophilus: a link in evolution of the tRNA-dependent amino acid amidation pathways

Thermus thermophilus possesses an aspartyl-tRNA synthetase (AspRS2) able to aspartylate efficiently tRNAAsp and tRNAAsn. Aspartate mischarged on tRNAAsn then is converted into asparagine by an omega amidase that differs structurally from all known asparagine synthetases. However, aspartate is not misincorporated into proteins because the binding capacity of aminoacylated tRNAAsn to elongation factor Tu is only conferred by conversion of aspartate into asparagine. T. thermophilus additionally contains a second aspartyl-tRNA synthetase (AspRS1) able to aspartylate tRNAAsp and an asparaginyl-tRNA synthetase able to charge tRNAAsn with free asparagine, although the organism does not contain a tRNA-independent asparagine synthetase. In contrast to the duplicated pathway of tRNA asparaginylation, tRNA glutaminylation occurs in the thermophile via the usual pathway by using glutaminyl-tRNA synthetase and free glutamine synthesized by glutamine synthetase that is unique. T. thermophilus is able to ensure tRNA aminoacylation by alternative routes involving either the direct pathway or by conversion of amino acid mischarged on tRNA. These findings shed light on the interrelation between the tRNA-dependent and tRNA-independent pathways of amino acid amidation and on the processes involved in fidelity of the aminoacylation systems.

New sequence-specific human ribonuclease: purification and properties

A new sequence-specific RNase was isolated from human colon carcinoma T84 cells. The enzyme was purified to electrophoretical homogeneity by pH precipitation, HiTrapSP and Superdex 200 FPLC. The molecular weight of the new enzyme, which we have named RNase T84, is 19 kDa. RNase T84 is an endonuclease which generates 5'-phosphate-terminated products. The new RNase selectively cleaved the phosphodiester bonds at AU or GU steps at the 3' side of A or G and the 5' side of U. 5'AU3' or 5'GU3' is the minimal sequence required for T84 RNase activity, but the rate of cleavage depends on the sequence and/or structure context. Synthetic ribohomopolymers such as poly(A), poly(G), poly(U) and poly(C) were very poorly hydrolysed by T84 enzyme. In contrast, poly(I) and heteroribopolymers poly(A,U) and poly(A,G,U) were good substrates for the new RNase. The activity towards poly(I) was stronger in two colon carcinoma cell lines than in three other epithelial cell lines. Our results show that RNase T84 is a new sequence-specific enzyme whose gene is abundantly expressed in human colon carcinoma cell lines.

Crystal structure of aspartyl-tRNA synthetase from Pyrococcus kodakaraensis KOD: archaeon specificity and catalytic mechanism of adenylate formation

The crystal structure of aspartyl-tRNA synthetase (AspRS) from Pyrococcus kodakaraensis was solved at 1.9 A resolution. The sequence and three-dimensional structure of the catalytic domain are highly homologous to those of eukaryotic AspRSs. In contrast, the N-terminal domain, whose function is to bind the tRNA anticodon, is more similar to that of eubacterial enzymes. Its structure explains the unique property of archaeal AspRSs of accommodating both tRNAAsp and tRNAAsn. Soaking the apo-enzyme crystals with ATP and aspartic acid both separately and together allows the adenylate formation to be followed. Due to the asymmetry of the dimeric enzyme in the crystalline state, different steps of the reaction could be visualized within the same crystal. Four different states of the aspartic acid activation reaction could thus be characterized, revealing the functional correlation of the observed conformational changes. The binding of the amino acid substrate induces movement of two invariant loops which secure the position of the peptidyl moiety for adenylate formation. An unambiguous spatial and functional assignment of three magnesium ion cofactors can be made. This study shows the important role of residues present in both archaeal and eukaryotic AspRSs, but absent from the eubacterial enzymes.

The protein component of Bacillus subtilis ribonuclease P increases catalytic efficiency by enhancing interactions with the 5' leader sequence of pre-tRNAAsp

Ribonuclease P (RNase P) is a ribonucleoprotein complex that catalyzes the formation of the mature 5' end of tRNA. To investigate the role of the protein component in enhancing the affinity of Bacillus subtilis RNase P for substrate (Kurz, J. C., Niranjanakumari, S., Fierke, C. A. (1998) Biochemistry 37, 2393), the kinetics and thermodynamics of binding and cleavage were analyzed for pre-tRNAAsp substrates containing 5' leader sequences of varying lengths (1-33 nucleotides). These data demonstrate that the cleavage rate constant catalyzed by the holoenzyme is not dependent on the leader length; however, the association rate constant for substrate binding to holoenzyme increases as the length of the leader increases, and this is reflected in enhanced substrate affinity of up to 4 kcal/mol. In particular, the protein component of RNase P stabilizes interactions with nucleotides at -2 and -5 in the 5' leader sequence of the pre-tRNA substrate. A 1 nucleotide leader decreases substrate affinity >/=15-fold compared to tRNAAsp due to ground-state destabilization of the enzyme-substrate complex. This destabilization is overcome by increasing the length of the leader to 2 nucleotides due to P RNA-pre-tRNA contacts that are stabilized by the P protein. The affinity of RNase P holoenzyme (but not RNA alone) for pre-tRNAAsp is further enhanced with a substrate containing a 5 nucleotide leader. These data indicate that novel direct or indirect interactions occur between the 5' leader sequence of pre-tRNAAsp and the protein component of RNase P.

The RNA sequence context defines the mechanistic routes by which yeast arginyl-tRNA synthetase charges tRNA

Arginylation of tRNA transcripts by yeast arginyl-tRNA synthetase can be triggered by two alternate recognition sets in anticodon loops: C35 and U36 or G36 in tRNA(Arg) and C36 and G37 in tRNA(Asp) (Sissler M, Giegé R, Florentz C, 1996, EMBO J 15:5069-5076). Kinetic studies on tRNA variants were done to explore the mechanisms by which these sets are expressed. Although the synthetase interacts in a similar manner with tRNA(Arg) and tRNA(Asp), the details of the interaction patterns are idiosyncratic, especially in anticodon loops (Sissler M, Eriani G, Martin F, Giegé R, Florentz C, 1997, Nucleic Acids Res 25:4899-4906). Exchange of individual recognition elements between arginine and aspartate tRNA frameworks strongly blocks arginylation of the mutated tRNAs, whereas full exchange of the recognition sets leads to efficient arginine acceptance of the transplanted tRNAs. Unpredictably, the similar catalytic efficiencies of native and transplanted tRNAs originate from different k(cat) and Km combinations. A closer analysis reveals that efficient arginylation results from strong anticooperative effects between individual recognition elements. Nonrecognition nucleotides as well as the tRNA architecture are additional factors that tune efficiency. Altogether, arginyl-tRNA synthetase is able to utilize different context-dependent mechanistic routes to be activated. This confers biological advantages to the arginine aminoacylation system and sheds light on its evolutionary relationship with the aspartate system.

Participation of the 3'-CCA of tRNA in the binding of catalytic Mg2+ ions by ribonuclease P

Ribonuclease P (RNase P) contains a catalytic RNA that cleaves precursor tRNA (pre-tRNA) to form the mature 5'-end of tRNA. Previous kinetic analyses with mutant pre-tRNAs indicated that both C residues of the invariant 3'-terminal CCA form specific interactions with RNase P RNA that contribute to the energetics of substrate binding (1, 2). In the present study, we have used single-turnover kinetic analysis to investigate whether specific changes in the 3'-terminal CCA influence the rate of the chemical step through which enzyme-bound substrate is converted to product (k2). At optimal ionic strength (1.0 M NH4Cl, 25 mM MgCl2), deletion or substitution of the 3'-proximal C residue (CCA) reduced the rate of the chemical step of cleavage (k2) by 60-fold. Similar changes to the 5'-proximal C residue (CCA) or the 3'-terminal A residue (CCA) reduced k2 only a few fold. Each mutant substrate exhibited weakened affinity for Mg2+, as measured by Hill plots, and the severity of these defects correlated with the observed reductions in k2. Furthermore, elevated concentrations of Mg2+ partially, but not completely, suppress the k2 defects caused by deletion or substitution of the 3'-proximal C residue. We conclude that the 3'-CCA of pre-tRNA, particularly the 3'-proximal C residue, comprises part of the catalytic pocket formed in the pre-tRNA-RNase P complex and participates in the binding of Mg2+ ions that are essential for catalysis by RNase P RNA.

Protein component of Bacillus subtilis RNase P specifically enhances the affinity for precursor-tRNAAsp

Ribonuclease P (RNase P) is an endonuclease that cleaves precursor tRNA to form the 5'-end of mature tRNA and is composed of a catalytic RNA subunit and a small protein subunit. The function of the protein component of Bacillus subtilis RNase P in catalysis of B. subtilis precursor tRNAAsp cleavage has been elucidated using steady-state kinetics, transient kinetics, and ligand affinity measurements to compare the functional properties of RNase P holoenzyme to RNase P RNA in 10 mM MgCl2, 100 mM NH4Cl. The protein component modestly affects several steps including </=10-fold increases in the rate constant for tRNA dissociation, the affinity of tRNA, and the rate constant for phosphodiester bond cleavage. However, the protein principally affects substrate binding, increasing the affinity of RNase P for pre-tRNAAsp by a factor of 10(4) as determined from both the ratio of the pre-tRNAAsp dissociation and association rate constants measured in 10 mM MgCl2 and a binding isotherm measured in 10 mM CaCl2 using gel filtration to separate enzyme-bound and free pre-tRNAAsp. Therefore, the main role of the protein component in RNase P is to facilitate recognition of pre-tRNA by enhancing the interaction between the enzyme and the 5'-precursor segment of the substrate, rather than stabilizing the tertiary structure of the folded RNA as has been observed for protein-facilitated group I intron self-splicing. Furthermore, the protein component maximizes the efficiency of RNase P under physiological conditions and minimizes product inhibition.

Site-specific cleavage of tRNA by imidazole and/or primary amine groups bound at the 5'-end of oligodeoxyribonucleotides

Sequence specific RNA cleaving molecules were synthesized by attaching novel polyamine derivatives bearing imidazole and/or primary amine groups to the 5'-end of DNA oligonucleotides as the sequence-recognizing moieties. The actions of the molecules on a half-tRNA(Asp) were investigated. The oligonucleotides directed the nuclease activity (the imidazole and the primary amine are the catalytic groups) of the enzyme to the nucleotides directly adjacent to the complementary target sequence on the substrate RNA. The cleavage reaction shows a bell-shaped pH dependence with a maximum at pH 7.0, indicating the participation of protonated and non-protonated imidazoles residues in the process. The specificity of these hybrid enzymes can be easily altered, and they should prove to be useful tools for probing RNA structures in solution and as potential reactive groups in antisense oligonucleotide derivatives. We also describe the site-specific cleavage of tRNA(Asp) by the cleaving reagents bearing imidazole and/or primary amine groups at the 5'-end of oligodeoxyribonucleotides.

tRNA is entrapped in similar, but distinct, nuclear and cytoplasmic ribonucleoprotein complexes, both of which contain vigilin and elongation factor 1 alpha

Vigilin, which is found predominantly in cells and tissues with high levels of protein biosynthesis, was isolated in its native form from human HEp-2 cells (A.T.C.C. CCL23) by immunoaffinity chromatography. Here we demonstrate that vigilin is part of a novel large tRNA-binding ribonucleoprotein complex (tRNP), found not only in the cytoplasm, but also in the nuclei of human cells. Compositional differences in the protein pattern were detected between the nuclear and cytoplasmic tRNPs, although some properties of the purified nuclear tRNP, such as tRNA protection against nuclease attack, were identical with those of the cytoplasmic tRNP. By using either a pool of total human nuclear RNA or radioactively labelled yeast tRNAAsp in rebinding experiments, we could show that tRNA is specifically recaptured by the RNA-depleted, vigilin-containing nuclear complex. We could also show that vigilin is capable of binding tRNA in vitro. Another tRNA-binding protein is elongation factor 1 alpha, which appears to be enriched in the cytoplasmic and nuclear tRNP complexes. This suggests that the cytoplasmic tRNP may be involved in the channelled tRNA cycle in the cytoplasm of eukaryotic cells. Our results also suggest that the nuclear vigilin-containing tRNP may be related to the nuclear export of tRNA.

A conserved aspartate of tRNA pseudouridine synthase is essential for activity and a probable nucleophilic catalyst

tRNA pseudouridine synthase I catalyzes the conversion of uridine to pseudouridine at positions 38, 39, and/or 40 in the anticodon loop of many tRNAs. Pseudouridine synthase I was cloned behind a T7 promoter and expressed in Escherichia coli to about 20% of total soluble proteins. Fluorouracil-substituted tRNA caused a time-dependent inactivation of pseudouridine synthase I and formed a covalent complex with the enzyme that involved the FUMP at position 39. Asp60, conserved in all known and putative pseudouridine synthases, was mutated to amino acids with diverse side chains. All Asp60 mutants bound tRNA but were catalytically inactive and failed to form covalent complexes with fluorouracil-substituted tRNA. We conclude that the conserved Asp60 is essential for pseudouridine synthase activity and propose mechanisms which involve this residue in important catalytic roles.

Mirror image alternative interaction patterns of the same tRNA with either class I arginyl-tRNA synthetase or class II aspartyl-tRNA synthetase

Gene cloning, overproduction and an efficient purification protocol of yeast arginyl-tRNA synthetase (ArgRS) as well as the interaction patterns of this protein with cognate tRNAArgand non-cognate tRNAAspare described. This work was motivated by the fact that the in vitro transcript of tRNAAspis of dual aminoacylation specificity and is not only aspartylated but also efficiently arginylated. The crystal structure of the complex between class II aspartyl-tRNA synthetase (AspRS) and tRNAAsp, as well as early biochemical data, have shown that tRNAAspis recognized by its variable region side. Here we show by footprinting with enzymatic and chemical probes that transcribed tRNAAspis contacted by class I ArgRS along the opposite D arm side, as is homologous tRNAArg, but with idiosyncratic interaction patterns. Besides protection, footprints also show enhanced accessibility of the tRNAs to the structural probes, indicative of conformational changes in the complexed tRNAs. These different patterns are interpreted in relation to the alternative arginine identity sets found in the anticodon loops of tRNAArgand tRNAAsp. The mirror image alternative interaction patterns of unmodified tRNAAspwith either class I ArgRS or class II AspRS, accounting for the dual identity of this tRNA, are discussed in relation to the class defining features of the synthetases. This study indicates that complex formation between unmodified tRNAAspand either ArgRS and AspRS is solely governed by the proteins.

Major identity determinants for enzymatic formation of ribothymidine and pseudouridine in the T psi-loop of yeast tRNAs

Almost all transfer RNA molecules sequenced so far contain two universal modified nucleosides at positions 54 and 55, respectively: ribothymidine (T54) and pseudouridine (psi 55). To identify the tRNA elements recognized by tRNA:m5uridine-54 methyltransferase and tRNA:pseudouridine-55 synthase from the yeast Saccharomyces cerevisiae, a set of 43 yeast tRNA(Asp) mutants were used. Some variants contained point mutations, while the others included progressive reductions in size down to a tRNA minisubstrate consisting of the T psi-loop with only one G.C base-pair as stem (9-mer). All substrates (full-sized tRNA(Asp) and various minihelices) were produced in vitro by T7 transcription and tested using yeast extract (S100) as a source of enzymatic activities and S-adenosyl-L-methionine as a methyl donor. The results indicate that the minimal substrate for enzymatic formation of psi 55 is a stem/loop structure with only four G.C base-pairs in the stem, while a longer stem is required for efficient T54 formation. None of the conserved nucleotides (G53, C56, A58 and C61) and U54 for psi 55 or U55 for T54 formation can be replaced by any of the other three canonical nucleotides. Yeast tRNA:m5uridine-54 methyltransferase additionally requires the presence of a pyrimidine-60 in the loop. Interestingly, in a tRNA(Asp) variant in which the T psi-loop was permuted with the anticodon-loop, the new U32 and U33 residues derived from the T psi-loop were quantitatively converted to T32 and psi 33, respectively. Structural mapping of this variant with ethylnitrosourea confirmed that the intrinsic characteristic structure of the T psi-loop was conserved upon permutation and that the displaced anticodon-loop did not acquire a T psi-loop structure. These results demonstrate that a local conformation rather than the exact location of the U-U sequence within the tRNA architecture is the important identity determinant for recognition by yeast tRNA:m5uridine-54 methyltransferase and tRNA:pseudouridine-55 synthase.

Rules governing the orientation of the 2'-hydroxyl group in RNA

Molecular dynamics simulations reveal that, in C3'-endo sugar puckers, only three orientations are accessible to the 2'-hydroxyl groups distinctive of RNA molecules: towards (i) the O3', (ii) the O4' of the same sugar, and (iii) the shallow groove base atoms. In the rarer C2'-endo sugar puckers, orientations towards the O3' atom of the same sugar are strongly favoured. Surprisingly, in helical regions, the frequently suggested intra-strand O2'-H(n)...O4'(n+1) interaction is not found. This observation led to the detection of an axial C-H...O interaction between the C2'-H2'(n) group and the O4'(n+1) atom contributing to the stabilization of RNA helical regions. Subsequent analysis of crystallographic structures of both RNA and A-DNA helices fully supports this finding. Specific hydration patterns are also thought to play a significant role in the stabilization of RNA structures. In the shallow groove of RNA, known as a favourable RNA or protein-binding region, three well-defined hydration sites are located around the O2' atom. These hydration sites, occupied by water molecules exchanging with the bulk, constitute, after dehydration, anchor points for specific interactions between RNA and nucleic acids, proteins or drugs. Therefore, the fact that the 2'-hydroxyl group is not monopolised by axial stabilization, together with its water-like behaviour, facilitates complex formation involving RNA helical regions.

Isoalloxazine derivatives promote photocleavage of natural RNAs at G.U base pairs embedded within helices

We have recently shown that isoalloxazine derivatives are able to photocleave RNA specifically at G.U base pairs embedded within a helical stack. The reaction involves the selective molecular recognition of G.U base pairs by the isoalloxazine ring and the removal of one nucleoside downstream of the uracil residue. Divalent metal ions are absolutely required for cleavage. Here we extend our studies to complex natural RNA molecules with known secondary and tertiary structures, such as tRNAs and a group I intron (td). G.U pairs were cleaved in accordance with the phylogenetically and experimentally derived secondary and tertiary structures. Tandem G.U pairs or certain G.U pairs located at a helix extremity were not affected. These new cleavage data, together with the RNA crystal structure, allowed us to perform molecular dynamics simulations to provide a structural basis for the observed specificity. We present a stable structural model for the ternary complex of the G. U-containing helical stack, the isoalloxazine molecule and a metal ion. This model provides significant new insight into several aspects of the cleavage phenomenon, mechanism and specificity for G. U pairs. Our study shows that in large natural RNAs a secondary structure motif made of an unusual base pair can be recognized and cleaved with high specificity by a low molecular weight molecule. This photocleavage reaction thus opens up the possibility of probing the accessibility of G.U base pairs, which are endowed with specific structural and functional roles in numerous structured and catalytic RNAs and interactions of RNA with proteins, in folded RNAs.

Structure and aminoacylation capacities of tRNA transcripts containing deoxyribonucleotides

The contribution of the ribose 2'-hydroxyls to RNA structure and function has been analyzed, but still remains controversial. In this work, we report the use of a mutant T7 RNA polymerase as a tool in RNA studies, applied to the aspartate and methionine tRNA aminoacylation systems from yeast. Our approach consists of determining the effect of substituting natural ribonucleotides by deoxyribonucleotides in RNA and, thereby, defining the subset of important 2'-hydroxyl groups. We show that deoxyribose-containing RNA can be folded in a global conformation similar to that of natural RNA. Melting curves of tRNAs, obtained by temperature-gradient gel electrophoresis, indicate that in deoxyribo-containing molecules, the thermal stability of the tertiary network drops down, whereas the stability of the secondary structure remains unaltered. Nuclease footprinting reveals a significant increase in the accessibility of both single- and double-stranded regions. As to the functionality of the deoxyribose-containing tRNAs, their in vitro aminoacylation efficiency indicates striking differential effects depending upon the nature of the substituted ribonucleotides. Strongest decrease in charging occurs for yeast initiator tRNA(Met) transcripts containing dG or dC residues and for yeast tRNA(Asp) transcripts with dU or dG. In the aspartate system, the decreased aminoacylation capacities can be correlated with the substitution of the ribose moieties of U11 and G27, disrupting two hydrogen bond contacts with the synthetase. Altogether, this suggests that specific 2'-hydroxyl groups in tRNAs can act as determinants specifying aminoacylation identity.

RNA hydration: three nanoseconds of multiple molecular dynamics simulations of the solvated tRNA(Asp) anticodon hairpin

The hydration of the tRNA(Asp) anticodon hairpin was investigated through the analysis of six 500 ps multiple molecular dynamics (MMD) trajectories generated by using the particle mesh Ewald method for the treatment of the long-range electrostatic interactions. Although similar in their dynamical characteristics, these six trajectories display different local hydration patterns reflecting the landscape of the "theoretical" conformational space being explored. The statistical view gained through the MMD strategy allowed us to characterize the hydration patterns around important RNA structural motifs such as a G-U base-pair, the anticodon U-turn, and two modified bases: pseudouridine and 1-methylguanine. The binding of ammonium counterions to the hairpin has also been investigated. No long-lived hydrogen bond between water and a 2'-hydroxyl has been observed. Water molecules with long-residence times are found bridging adjacent pro-Rp phosphate atoms. The conformation of the pseudouridine is stiffened by a water-mediated base-backbone interaction and the 1-methylguanine is additionally stabilized by long-lived hydration patterns. Such long-lived hydration patterns are essential to ensure the structural integrity of this hairpin motif. Consequently, our simulations confirm the conclusion reached from an analysis of X-ray crystal structures according to which water molecules form an integral part of nucleic acid structure. The fact that the same conclusion is reached from a static and a dynamic point of view suggests that RNA and water together constitute the biologically relevant functional entity.

Purification and characterization of the precursor tRNA 3'-end processing nuclease from Aspergillus nidulans

The precursor-tRNA 3'-end processing nuclease activity was purified homogeneously about 15,300 fold from the heat-treated fraction. The precursor-tRNA 3'-end processing nuclease was a single polypeptide of 160,000 Da. This nuclease generates a mature 3'-end of nuclear tRNA(Asp) of Aspergillus nidulans by the endonuclease activity and prefers the 5'-end processed tRNA(Asp) rather than primary precursor-tRNA(Asp) as a substrate. However, this enzyme did not process both primary mitochondrial precursor-tRNA(His) and 5'-end processed mitochondrial precursor-tRNA(His) of A. nidulans.

RNA editing changes the identity of a mitochondrial tRNA in marsupials

In the mitochondrial genome of marsupials, the tRNA gene located at the position where in other mammals an aspartyl-tRNA is encoded carries the glycine anticodon GCC. Post-transcriptionally, an RNA editing mechanism affects the second position of the anticodon such that the aspartate anticodon GUC is created in approximately 50% of the mature tRNA pool. We show that the unedited version of this tRNA'Asp' (GCC) can be specifically aminoacylated with glycine in vitro, while the edited version becomes aminoacylated with aspartic acid. Furthermore, we show that both forms are aminoacylated to a substantial extent in vivo. By replacing an amino group with a keto group, RNA editing thus changes the identity of this tRNA allowing a single gene to encode two tRNAs.

Unusual enzyme characteristics of aspartyl-tRNA synthetase from hyperthermophilic archaeon Pyrococcus sp. KOD1

The aspA gene, encoding the aspartyl-tRNA synthetase (AspRS) from the hyperthermophilic archaeon Pyrococcus sp. KOD1, was expressed in Escherichia coli. The KOD1 AspRS, which was purified to homogeneity and was shown to be functional in dimeric form, aminoacylated tRNA from KOD1. The optimum temperature for this activity was 65 degrees C, which was lower than that for the cell growth of KOD1 (85 degrees C). However, it increased to 75 degrees C by the addition of polyamine molecules, such as putrescine, spermine, and spermidine. Analysis of the thermal denaturations of the enzyme and of KOD1-tRNA indicated that neither of them was denatured at temperatures below 70 degrees C. These results suggest polyamine is one of the factors which are required to stabilize the AspRS-tRNA complex in vivo. In order to determine whether the nucleotide triphosphate (NTP) is required for Asp-tRNA synthesis, the aminoacylation was examined in the presence of each of the four NTPs. AspRS most effectively aminoacylated tRNA in the presence of ATP. However, we also found that the enzyme aminoacylated it even in the presence of GTP and UTP as well. Archaeon synthetase may have an interesting system to utilize other NTPs than ATP. The extreme conditions of early life may have given rise to these unique characteristics which then disappeared from developed organisms through evolution.

Arginine aminoacylation identity is context-dependent and ensured by alternate recognition sets in the anticodon loop of accepting tRNA transcripts

Yeast arginyl-tRNA synthetase recognizes the non-modified wild-type transcripts derived from both yeast tRNA(Arg) and tRNA(Asp) with equal efficiency. It discriminates its cognate natural substrate, tRNA(Arg), from non-cognate tRNA(Asp) by a negative discrimination mechanism whereby a single methyl group acts as an anti-determinant. Considering these facts, recognition elements responsible for specific arginylation in yeast have been searched by studying the in vitro arginylation properties of a series of transcripts derived from yeast tRNA(Asp), considered as an arginine isoacceptor tRNA. In parallel, experiments on similar tRNA(Arg) transcripts were performed. Unexpectedly, in the tRNA(Arg) context, arginylation is basically linked to the presence of residue C35, whereas in the tRNA(Asp) context, it is deeply related to that of C36 and G37 but is insensitive to the nucleotide at position 35. Each of these nucleotides present in one host, is absent in the other host tRNA. Thus, arginine identity is dependent on two different specific recognition sets according to the tRNA framework investigated.

Magnesium ions are required by Bacillus subtilis ribonuclease P RNA for both binding and cleaving precursor tRNAAsp

The multiple roles Mg2+ plays in ribozyme-catalyzed reactions in stabilizing RNA structure, enhancing the affinity of bound substrates, and increasing catalysis are delineated for the RNA component of ribonuclease P (RNase P RNA) by a combination of steady-state kinetics, transient kinetics, and equilibrium binding measurements. Divalent metal ions cooperatively increase the affinity of Bacillus subtilis RNase P RNA for B. subtilis tRNA(Asp) more than 10(3)-fold, consistent with at least two additional magnesium ions binding to the RNase P RNA.tRNA complex. Monovalent cations also decrease KD(tRNA) and reduce, but do not eliminate, the dependence on magnesium ions, demonstrating that nonspecific electrostatic shielding is not sufficient to explain the requirement for high salt. Both di- and monovalent cations promote the high affinity of tRNA by forming contacts in the binary complex that reduce the dissociation rate constant for tRNA. Additionally, the hyperbolic dependence of the hydrolytic rate constant on the concentration of magnesium with a K1/2 approximately equal to 36 mM suggests that a third low-affinity divalent metal ion stabilizes the transition state for pre-tRNA cleavage. Furthermore, many (about 100) magnesium ions bind independently to RNase P RNA with higher affinity than the K1/2 of any of the functionally characterized magnesium binding sites. Therefore, the magnesium binding sites that have differential affinity in either the "folded" species or binary complex are a small subset of the total number of associated magnesium ions. In summary, the importance of magnesium bound to RNase P RNA can be separated functionally into three crucial roles: at least three sites stabilize the folded RNA tertiary structure [Pan. T. (1995) Biochemistry 34, 902-909], at least two sites enhance the formation of complexes of RNase P RNA with pre-tRNA or tRNA, and at least one site stabilizes the transition state for pre-tRNA cleavage.

Asn-tRNA in Lactobacillus bulgaricus is formed by asparaginylation of tRNA and not by transamidation of Asp-tRNA

In many organisms (e.g., gram-positive eubacteria) Gin-tRNA is not formed by direct glutaminylation of tRNAGln but by a specific transamidation of Glu-tRNAGln. We wondered whether a similar transamidation pathway also operates in the formation of Asn-tRNA in these organisms. Therefore we tested in S-100 preparations of Lactobacillus bulgaricus, a gram-positive eubacterium, for the conversion by an amidotransferase of [14C]Asp-tRNA to [14C]Asn-tRNA. As no transamidation was observed, we searched for genes for asparaginyl-tRNA synthetase (AsnRS). Two DNA fragments (from different locations of the L.bulgaricus chromosome) were found each containing an ORF whose sequence resembled that of the Escherichia coli asnS gene. The derived amino acid sequences of the two ORFs (432 amino acids) were the same and 41% identical with E.coli AsnRS. When one of the ORFs was expressed in E.coli, it complemented the temperature sensitivity of an E.coli asnS mutant. S-100 preparations of this transformant showed increased charging of unfractionated L.bulgaricus tRNA with asparagine. Deletion of the 3'-terminal region of the L.bulgaricus AsnRS gene led to loss of its complementation and aminoacylation properties. This indicates that L.bulgaricus contains a functional AsnRS. Thus, the transamidation pathway operates only for Gin-tRNAGln formation in this organism, and possibly in all gram-positive eubacteria.