The Gcd10p/Gcd14p complex is the essential two-subunit tRNA(1-methyladenosine) methyltransferase of Saccharomyces cerevisiae

The modified nucleoside 1-methyladenosine (m(1)A) is found at position 58 in the TPsiC loop of many eukaryotic tRNAs. The absence of m(1)A from all tRNAs in Saccharomyces cerevisiae mutants lacking Gcd10p elicits severe defects in processing and stability of initiator methionine tRNA (tRNA(i)(Met)). Gcd10p is found in a complex with Gcd14p, which contains conserved motifs for binding S-adenosylmethionine (AdoMet). These facts, plus our demonstration that gcd14Delta cells lacked m(1)A, strongly suggested that Gcd10p/Gcd14p complex is the yeast tRNA(m(1)A)methyltransferase [(m(1)A)MTase]. Supporting this prediction, affinity-purified Gcd10p/Gcd14p complexes used AdoMet as a methyl donor to synthesize m(1)A in either total tRNA or purified tRNA(i)(Met) lacking only this modification. Kinetic analysis of the purified complex revealed K(M) values for AdoMet or tRNA(i)(Met) of 5.0 microM and 2.5 nM, respectively. Mutations in the predicted AdoMet-binding domain destroyed GCD14 function in vivo and (m(1)A)MTase activity in vitro. Purified Flag-tagged Gcd14p alone had no enzymatic activity and was severely impaired for tRNA-binding compared with the wild-type complex, suggesting that Gcd10p is required for tight binding of the tRNA substrate. Our results provide a demonstration of a two-component tRNA MTase and suggest that binding of AdoMet and tRNA substrates depends on different subunits of the complex.

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.

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

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

Characterisation and enzymatic properties of tRNA(guanine 26, N (2), N (2))-dimethyltransferase (Trm1p) from Pyrococcus furiosus

The structural gene TRM1 encoding tRNA(guanine 26, N (2), N (2))-dimethyltransferase (Trm1p) of the hyperthermophilic archaeon Pyrococcus furiosus was cloned and expressed in Escherichia coli. The corresponding recombinant enzyme (pfTrm1p) with a His6-tag at the N terminus was purified to homogeneity in three steps. The enzyme has a native molecular mass of 49 kDa (as determined by gel filtration) and is very stable to heat denaturation (t1/2at 95 degrees C is two hours). pfTrm1p is a monomer and forms a one to one complex with T7 transcripts of yeast tRNA(Phe). It methylates a single guanine residue at position 26 using S -adenosyl- l -methionine as donor of the methyl groups. Depending on the incubation temperature, the type of tRNA transcript and the ratio of enzyme to tRNA, m(2)G26 or m(2)2G26 was the main product. The addition of the second methyl group to N (2)guanine 26 takes place in vitro through a monomethylated intermediate, and the enzyme dissociates from its tRNA substrate between the two consecutive methylation reactions. Identity elements in tRNA for mono- and dimethylation reactions by the recombinant pfTrm1p were identified using in vitro T7 transcripts of 33 variants of tRNA(Asp)and tRNA(Phe)from yeast. The efficient dimethylation of G26 requires the presence of base-pairs C11.G24 and G10.C25 and a variable loop of five bases within a correct 3D-core of the tRNA molecule. These identity elements probably ensure the correct presentation of monomethylated m(2)G26 to the enzyme for the attachment of the second methyl group. In contrast, the structural requirements for monomethylation of the same guanine 26 are much more relaxed and tolerate variations in the base-pairs of the D-stem, in the size of the variable loop or distortions of the 3D-architecture of the tRNA molecule.

Multisite-specific tRNA:m5C-methyltransferase (Trm4) in yeast Saccharomyces cerevisiae: identification of the gene and substrate specificity of the enzyme

Several genes encoding putative RNA:5-methylcytidine-transferases (m5C-transferases) from different organisms, including yeast, have been identified by sequence homology with the recently identified 16S rRNA:m5C967-methyltransferase (gene SUN) from Escherichia coli. One of the yeast ORFs (YBL024w) was amplified by PCR, inserted in the expression vector pET28b, and the corresponding protein was hyperexpressed in E. coli BL21 (DE3). The resulting N-terminally His6-tagged recombinant Ybl024p was purified to apparent homogeneity by one-step affinity chromatography on Ni2+-NTA-agarose column. The activity and substrate specificity of the purified Ybl024p were tested in vitro using T7 transcripts of different yeast tRNAs as substrates and S-adenosyl-L-methionine as a donor of the methyl groups. The results indicate that yeast ORF YBL024w encodes S-adenosyl-L-methionine-dependent tRNA: m5C-methyltransferase that is capable of methylating cytosine to m5C at several positions in different yeast tRNAs and pre-tRNAs containing intron. Modification of tRNA occurs at all four positions (34, 40, 48, and 49) at which m5C has been found in yeast tRNAs sequenced so far. Disruption of the ORF YBL024w leads to the complete absence of m5C in total yeast tRNA. Moreover no tRNA:m5C-methyltransferase activity towards all potential m5C methylation sites was detected in the extract of the disrupted yeast strain. These results demonstrate that the protein product of a single gene is responsible for complete m5C methylation of yeast tRNA. Because this newly characterized multisite-specific modification enzyme Ybl024p is the fourth tRNA-specific methyltransferase identified in yeast, we suggest designating it as TRM4, the gene corresponding to ORF YBL024w.

Synthesis and methyltransferase activity of nonstructural protein nsP1 in Sindbis virus-infected Aedes albopictus cells

To investigate the synthesis and turnover of the nonstructure protein, nsP1, in Aedes albopictus cells, we labeled infected cells with [35S]-methionine and immunoprecipitated nsP1 with a polyclonal monospecific rabbit antibody. Synthesis of nsP1 in mosquito cells could be detected 2 hr after infection and continued as long as 24 hr post-infection, regardless whether the infected cells were maintained at 28 degrees C , 34.5 degrees C , or 37 degrees C. Whereas the time pattern of nsP1 synthesis varied with temperature. Nonstructural protein 1 synthesis at 28 degrees C was maximal at 4 hr, then decreased. At 37 degrees C synthesis reached a high level at 2 hr and remained constant for 24 hr. Pulse-chase experiments showed that nsP1 in mosquito cells, whether made as early as 5 hr post-infection or as late as 24 hr, were stable during that time, the longest period tested. Enzyme activity reached a maximum at 10 hr and remained almost the same level until 24 hr. The yield of Sindbis virus from mosquito cells was higher at 34.5 degrees C and 37 degrees C than at 28 degrees C. Methyltransferase activity was needed for modification of positive-strand genomic and subgenomic RNAs. The activity of methyltransferase observed until late in the replication cycle probably accounted for both the continued synthesis and minimal turnover of nsP1.

Transfer RNA modification enzymes from Pyrococcus furiosus: detection of the enzymatic activities in vitro

The modification patterns of in vitro transcripts of two yeast Saccharomyces cerevisiae tRNAs (tRNAPheand tRNAAsp) and one archaeal Haloferax volcanii tRNA (tRNAIle) were investigated in the cell-free extract of Pyrococcus furiosus supplemented with S -adenosyl-l-methionine (AdoMet). The results indicate that the enzymatic formation of 11 distinct modified nucleotides corresponding to 12 enzymatic activities can be detected in vitro. They correspond to the formation of pseudouridines (Psi) at positions 39 and 55, 2' -O- ribose methylations at positions 6 (Am) and 56 (Cm), base methylations at positions 10 (m2G), 26 (m22G), 37 (m1G), 49 (m5C), 54 (m5U) and 58 (m1A) and both the deamination and methylation of adenosine into m1I at position 57. Most of the detected modified nucleotides are common modifications found in other phylogenetic groups, while Am6, Cm56and m1I57are specific modifications found exclusively in Archaea. It is also shown that the enzymatic formation of m5C49, m5U54, Psi55and m1I57does not depend on the three-dimensional architecture of the tRNA substrate, since these modi-fications also occur in fragmented tRNAs as substrate.

Caenorhabditis elegans ZC376.5 encodes a tRNA (m2/2G(26))dimethyltransferance in which (246)arginine is important for the enzyme activity

It has been estimated that eukaryotes carry more than 50 genes for tRNA modifying enzymes. Of the few so far identified most come from yeast, a lower eukaryote. In Saccharomyces cerevisiae, the TRM1 gene is a nuclear gene encoding the tRNA(m2/ 2G(26))dimethyltransferase, which catalyses the formation of the N2, N2-dimethylguanosine at position 26 in tRNA. We have isolated and characterized the corresponding gene ZC376.5 in Caenorhabditis elegans. Via RTPCR the cDNA sequence of the full length ZC376.5 has now been cloned, expressed in Escherichia coli and demonstrated to encode a tRNA(m2/2G(26))dimethyltransferase that produces dimethyl-G26 in vivo and in vitro with tRNA from yeast and bacteria as substrates. This is the first example of a complete gene sequence coding for a tRNA modifying enzyme from a multicellular organism. A point mutation in exon IV in the C. elegans genome sequence coding for the tRNA(m2/2G(26))methyltransferase that substituted arginine246 for glycine eliminated the modification activity. Exchanging the corresponding lysine residue in the yeast Trm1p for alanine caused a severe loss of activity, indicating that the identity of the amino acid at this position is important for enzyme activity.

A pseudoknotted tRNA variant is a substrate for tRNA (cytosine-5)-methyltransferase from Xenopus laevis

tRNA post-transcriptional modification enzymes of Xenopus laevis were proposed previously to belong to two major groups according to their sensitivity to structural perturbations in their substrates. To further investigate the structural variations tolerated by these enzymes, the tRNA-like domain of turnip yellow mosaic virus RNA (88 nucleotides in length) has been microinjected into the oocytes of Xenopus laevis. This RNA possesses 12 potential target nucleotides for modification within a structure including a pseudoknotted folding, an extended anticodon stem, and unusual D-loop/T-loop interactions. Results indicate that only cytosine-42, a position equivalent to C-49 in canonical tRNAs, was quantitatively modified into m5C in the microinjected RNA. Modification was detected to high levels, indicating that at least one enzyme tolerates non-canonical structural features.

Point and deletion mutations eliminate one or both methyl group transfers catalysed by the yeast TRM1 encoded tRNA (m22G26)dimethyltransferase

Guanosine at position 26 in eukaryotic tRNAs is usually modified to N2 , N2 -dimethylguanosine (m22G26). In Saccharomyces cerevisiae , this reaction is catalysed by the TRM1 encoded tRNA (m22G26)dimethyltransferase. As a prerequisite for future studies, the yeast TRM1 gene was expressed in Escherichia coli and the His-tagged Trm1 protein (rTrm1p) was extensively purified. rTrm1p catalysed both the mono- and dimethylation of G26 in vivo in Escherichia coli tRNA and in vitro in yeast trm1 mutant tRNA. The TRM1 gene from two independent wild-type yeast strains differed at 14 base positions causing two amino acid exchanges . Exchange of the original Ser467 for Leu caused a complete loss of enzyme activity in vitro against trm1 yeast tRNA. Comparatively short N- or C-terminal deletions from the 570 amino acid long Trm1 polypeptide decreased or eliminated the enzyme activity, as did some point mutations within these regions. This indicated that the protein is not a two domain peptide with the enzyme activity localised to one of the domains, but rather that both ends of the polypeptide seem to interact to influence the conformation of those parts that make up the RNA-binding site and/or the active site of the enzyme.

Small structural ensembles for a 17-nucleotide mimic of the tRNA T psi C-loop via fitting dipolar relaxation rates with the quadratic programming algorithm

Solution structures are typically average structures determined with the help of nmr-derived distance and torsion angle information. However, when a biomolecule populates significantly different conformations, the average structure might be prone to artifacts, and other refinement strategies are necessary. For example, when experimental restraints are used in molecular dynamics simulations in a time-averaged fashion (MDtar), the experimental structural information does no longer need to be satisfied at each step of the simulation; instead, the whole trajectory must agree with the restraints. However, the resulting structural ensembles are large and not unique and it is not trivial to extract the essential dynamic features for a system. Here we demonstrate that large MDtar ensembles can be simplified substantially by reducing the number of members to just a few on the basis of adjusting the individual probabilities of the members with the PDQPRO program [N. B. Ulyanov et al. Biophysical Journal (1995), Vol. 68, p. 13]. This algorithm finds the global minimum for a search function that represents the best match of a given ensemble with the experimental dipolar interproton relaxation rates. We have applied this strategy to a 17-residue RNA hairpin, whose loop exhibited considerable flexibility evident from nmr data. This 17mer is a mimic of the T psi C-loop of tRNA, where nucleotide 54 is usually a ribosylthymidine. The methylation of U54, which is completely buried in transfer ribonucleic acid, is administered by tRNA (m5 U54)-methyltransferase (RUMT). Since the 17mer is a good substrate for RUMT, we previously concluded that the flexibility of the 17mer's loop is a key to how RUMT gains access to the methylation site [L. J. Yao et al. Journal of Biomolecular NMR (1996) Vol. 9. p. 229]. Application of the PDQPRO algorithm to the previously acquired MDtar trajectories allowed us to reduce the number of conformations from several hundred to one major and five or six minor conformations with individual populations from approximately 5% to approximately 50% without any deterioration in the match with the experimental data. The major conformation exhibits a continuation of A-form helicity through part of the loop, involving C60 and U59. In this and most other conformations the methylation site in U54 is no longer buried.

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.

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.

Essentially minimal sequence for substrate recognition by tRNA (guanosine-2')-methyltransferase from Thermus thermophilus HB27

Transfer RNA (guanosine-2'-)-methyltransferase (Gm-methylase, EC.2.1.1.32) from extreme thermophile, Thermus thermophilus HB27 is one of the tRNA-ribose modification enzymes; this enzyme specifically catalyze the transfer of a methyl group from S-adenosyl-L-methionine to 2'-OH of the ribose of the guanosine at position 18 in tRNA. A broad substrate specificity of Gm-methylase was observed using natural tRNAs as methyl group acceptors, which suggests that some local stractures common in tRNAs are recognized by the enzyme. By using yeast tRNA(Phe) variants obtained by transcription of their genes with T7 RNA polymerase, it was revealed that the residues G18 and G19, as well as the D-stem structure were primarily required for the methylation reaction and that the essentially minimal sequence for the substrate was Pyrimidine17-G18-G19. The other conserved sequences and the tertiary base-pairs were not essential, but G15, G46, U55 and C56 strongly affected the methylation efficiency.

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.

tRNA recognition for modification: solution probing of tRNA complexed with Escherichia coli tRNA (guanosine-1) methyltransferase

The interaction of Escherichia coli tRNA (guanosine-1) methyltransferase and tRNA(1Leu) transcripts has been probed using cleavage with iodine of phosphorothioate-substituted transcripts, lead acetate, and enzymes specific for single- and double-stranded RNA. All lytic agents protect the anticodon stem-loop and variable loop regions against cleavage, and some protection is also seen in core structures of the tRNA. Residues from both strands of the anticodon stem are protected against cleavage with iodine and lead by enzyme, yet positions G37 and G36, which are crucial for catalysis and binding, are not. This suggests that these residues may undergo structural perturbation in the presence of S-adenosyl methionine. Occupancy of the AdoMet site by the product S-adenosyl-homocysteine, a potent inhibitor of the enzyme, has little or no effect on tRNA binding or protection. Enhanced reactivity with lead is seen at residues located in the anticodon stem-loop, extra-loop, and core (C34, U47c, and G49), which suggests some perturbations in RNA structure might accompany binding.

The spoU gene of Escherichia coli, the fourth gene of the spoT operon, is essential for tRNA (Gm18) 2'-O-methyltransferase activity

We have evidence that the open reading frame previously denoted spoU is necessary for tRNA (Gm18) 2'-O-methyltransferase activity. The spoU gene is located in the gmk-rpoZ-spoT-spoU-recG operon at 82 minutes on the Escherichia coli chromosome. The deduced amino acid sequence of spoU shows strong similarities to previously characterized 2'-O-methyltransferases. Comparison of the nucleoside modification pattern of hydrolyzed tRNA, 16S rRNA and 23S rRNA from wild-type and spoU null mutants showed that the modified nucleoside 2'-O-methylguanosine (Gm), present in a subset of E. coli tRNAs at residue 18, is completely absent in the spoU mutant, suggesting that spoU encodes tRNA (Gm18) 2'-O-methyltransferase. Nucleoside modification of 16S and 23S rRNA was unaffected in the spoU mutant. Insertions in the downstream recG gene did not affect RNA modification. Absence of Gm18 in tRNA does not influence growth rate under the tested conditions and does not interfere with activity of the SupF amber suppressor, a suppressor tRNA that normally has the Gm18 modification. We suggest that the spoU gene be renamed trmH (tRNA methylation).

Interaction of tRNA with tRNA (guanosine-1)methyltransferase: binding specificity determinants involve the dinucleotide G36pG37 and tertiary structure

The sequence G37pG36 is present in all tRNA species recognized and methylated by the Escherichia coli modification enzyme tRNA (guanosine-1)methyltransferase. We have examined whether this dinucleotide sequence provides the base specific recognition signal for this enzyme and have assessed the role of the remaining tRNA in recognition. E. coli tRNAHis and yeast tRNAAsp were substituted with G at positions 36 and 37 and were found to be excellent substrates for methylation. This suggested that the general tRNA structure can be specifically bound by the enzyme. In addition, heterologous tRNA species including fully modified tRNA1Leu are excellent inhibitors of tRNA1Leu transcript methylation. Analyses of structural variants of yeast tRNAAsp and E. coli tRNA1Leu demonstrate clearly that the core tertiary structures of tRNA are required for recognition and that G37 must be in the correct position in space relative to important contacts elsewhere in the molecule. This latter conclusion was reached because the addition of one to three stacked base pairs in the anticodon stem of tRNA1Leu dramatically alters activity. In this case, the G37 base is rotated away from the correct position in space relative to other tRNA contact sites. The acceptor stem structure is required for optimal activity since deletion of three or five base pairs is detrimental to activity; however, specific base sequence may not be important because (i) the addition of three stacked base pairs of different sequence had little effect on activity and (ii) heterologous tRNAs with little or no sequence homology in the acceptor stem are excellent substrates. Both poly G and GpG are potent and specific inhibitors of enzyme activity and are minimal substrates which can be methylated, forming m1G. Taken together, these studies suggest that 1MGT can bind the general tRNA structure and that the crucial base-pair contacts are G37 and G36.

Intron-dependent enzymatic formation of modified nucleosides in eukaryotic tRNAs: a review

In eukaryotic cells, especially in yeast, several genes encoding tRNAs contain introns. These are removed from pre-tRNAs during the maturation process by a tRNA-specific splicing machinery that is located within the nucleus at the nuclear envelope. Before and after the intron removal, several nucleoside modifications are added in a stepwise manner, but most of them are introduced prior to intron removal. Some of these early nucleoside modifications are catalyzed by intron-dependent enzymes while most of the others are catalyzed in an intron-independent manner. In the present paper, we review all known cases where the nucleoside modifications were shown to depend strictly on the presence of an intron. These are pseudouridines at anticodon positions 34, 35 and 36 and 5-methylcytosine at position 34 of several eukaryotic tRNAs. One common property of the corresponding intron-dependent modifying enzymes is that their activities are essentially dependent on the local specific architecture of the pre-tRNA molecule that comprises the anticodon stem and loop prolonged by the intron domain. Thus introns clearly serve as internal (cis-type) RNAs that guide nucleoside modifications by providing transient target sites in tRNA for selected nuclear modifying enzymes. This situation may be similar to the recently discovered (trans-type) snoRNA-guided process of ribose methylations of ribosomal RNAs within the nucleolus of eukaryotic cells.

The dynamic NMR structure of the T psi C-loop: implications for the specificity of tRNA methylation

tRNA (m5U54)-methyltransferase (RUMT) catalyzes the S-adenosylmethionine-dependent methylation of uridine-54 in the T psi C-loop of all transfer RNAs in E. coli to form the 54-ribosylthymine residue. However, in all tRNA structures, residue 54 is completely buried and the question arises as to how RUMT gains access to the methylation site. A 17-mer RNA hairpin consisting of nucleotides 49-65 of the T psi-loop is a substrate for RUMT. Homonuclear NMR methods in conjunction with restrained molecular dynamics (MD) methods were used to determine the solution structure of the 17-mer T-arm fragment. The loop of the hairpin exhibits enhanced flexibility which renders the conventional NMR average structure less useful compared to the more commonly found situation where a molecule exists in predominantly one major conformation. However, when resorting to softer refinement methods such as MD with time-averaged restraints, the conflicting restraints in the loop can be satisfied much better. The dynamic structure of the T-arm is represented as an ensemble of 10 time-clusters. In all of these, U54 is completely exposed. The flexibility of the T psi-loop in solution in conjunction with extensive binding studies of RUMT with the T psi C-loop and tRNA suggest that the specificity of the RUMT/ tRNA recognition is associated with tRNA tertiary structure elements. For the methylation, RUMT would simply have to break the tertiary interactions between the D- and T-loops, leading to a melting of the T-arm structure and making U54 available for methylation.

Structural requirements for the formation of 1-methylguanosine in vivo in tRNA(Pro)GGG of Salmonella typhimurium

Maturation of tRNA and rRNA and the assembly of the ribosome in all organisms occurs in vivo in a complex pathway in which various proteins such as endo- and exonucleases, tRNA and rRNA modifying enzymes and ribosomal proteins, act concomitantly and temporarily during the maturation process. One class of RNA binding proteins are the tRNA modifying enzymes, which catalyse the formation of various modified nucleosides present in tRNA. Here we analyse the consequences of various alterations in a tRNA on the formation of modified nucleosides in the tRNA and the aminoacylation of it under true in vivo conditions, i.e. in a cell with normal amounts of the tRNA substrate and the tRNA binding protein. We have devised a selection method to obtain mutants of tRNA(Pro)GGG in Salmonella typhimurium that may no longer be a substrate inl vivo for the tRNA(m1G37)methyltransferase. These mutant tRNAs were purified from cells in balanced growth by a solid phase hybridisation technique and the presence of 1-methylguanosine (m1G) in position 37 next to the anticodon was monitored. Of 13 different mutant tRNA(Pro)GGG species analysed, eight of them had a drastically reduced level of m1G. Some of these mutant tRNA species had alterations far from the nucleotide G37 modified by the enzyme; e.g. base-pair disruptions in the first, fourth and eighth (last) base-pair of the acceptor stem, in the D-stem, and in the top of the anticodon stem. The structure of all the mutant tRNA(Pro)GGG species must deviate from the wild-type form, since they all induced +1 frameshifting. Still, tRNA(Pro)GGG from five of the mutants had normal levels of m1G. Thus, only a subset of mutations, all inducing an altered tRNA structure, resulted in m1G deficiency. However, those alterations in tRNA(Pro)GGG, which influenced the tRNA(m1G37)methyltransferase activity, did not affect in vivo the formation of four other modified nucleosides and the aminoacylation of tRNA(Pro)GGG, demonstrating the extreme dependence of the tRNA(m1G37)methyltransferase on an almost perfect three-dimensional structure of the tRNA. We discuss that the conformation of the anticodon loop may be a major determining element for the formation of m1G37 in vivo.

Recognition of the T-arm of tRNA by tRNA (m5U54)-methyltransferase is not sequence specific

tRNA (m5U54)-methyltransferase (RUMT) catalyzes the methylation of U54 of tRNAs. In contrast to enzymes which recognize a particular tRNA, RUMT recognizes features common to all tRNAs. We have shown that these features reside in the T-arm of tRNA and constructed a minimal consensus sequence for RUMT recognition and catalysis (Gu et al., 1991b). Here, we have mutated each conserved T-loop residue and conserved T-stem base pair to bases or base pairs which are not observed in Escherichia coli tRNA. The substrate specificity of RUMT for 30 in vitro synthesized T-arm mutants of tRNAPhe and 37 mutants of the 17-mer analog of the T-arm derived from tRNA1Val was investigated. A 2-5 base pair stem was essential for recognition of the T-arm by RUMT, but the base composition of the stem was unimportant. The 7-base size of the T-loop maintained by the stem was essential for RUMT recognition. For tRNA, most base substitutions in the 7-base loop did not eliminate RUMT activity, except for any mutation of the methyl acceptor U54 and the C56G mutation. The effect of base and base pair mutations on Kcat or the rate of methylation by RUMT was more striking than the effect on the Kd for binding to RUMT. In comparison with mutations in the T-loop of intact tRNA, base mutation in the T-loop of the 17-mer T-arm had a more deleterious effect on binding and methylation. Surprisingly, recognition of tRNA by RUMT appears to reside in the three-dimensional structure of the seven-member T-loop rather than in its primary structure.

Site-specific ribose methylation of preribosomal RNA: a novel function for small nucleolar RNAs

Eukaryotic cells contain many fibrillarin-associated small nucleolar RNAs (snoRNAs) that possess long complementarities to mature rRNAs. Characterization of 21 novel antisense snoRNAs from human cells followed by genetic depletion and reconstitution studies on yeast U24 snoRNA provides evidence that this class of snoRNAs is required for site-specific 2'-O-methylation of preribosomal RNA (pre-rRNA). Antisense sno-RNAs function through direct base-pairing interactions with pre-rRNA. The antisense element, together with the D or D' box of the snoRNA, provide the information necessary to select the target nucleotide for the methyltransfer reaction. The conclusion that sno-RNAs function in covalent modification of the sugar moieties of ribonucleotides demonstrates that eukaryotic small nuclear RNAs have a more versatile cellular function than earlier anticipated.

Effect of hypoxia on hepatic DNA methylation and tRNA methyltransferase in rat: similarities to effects of methyl-deficient diets

Young rats were maintained in a 10% oxygen atmosphere for 2, 6, and 10 days and administered normal rat chow and water ad libitum. Thereafter, their hepatic S-adenosyl-L-methionine (AdoMet) and activity and mRNA levels of AdoMet synthetase were assayed. AdoMet levels decreased by 45% after 10 days; hepatic AdoMet synthetase also declined by approximately 40%. In rats with low hepatic AdoMet, the mRNA level of AdoMet synthetase also declined by up to 80%. No significant change in AdoMet or AdoMet synthetase was noted in pair-fed normoxic rats. DNA hypomethylation was determined in terms of incorporation of [3H]methyl of AdoMet incorporated at unmethylated sites in DNA in reactions mediated by methylases HpaII and SssI. As compared to the normal hepatic DNA, [3H]methyl group incorporation in the 10-day hypoxic DNA was almost double in the HpaII-mediated reaction and approximately 10-fold in the SssI-mediated reaction. Hepatic tRNA methyltransferase activity doubled after 10 days of hypoxia. However, hypoxic rats showed no detectable mRNA transcripts for c-myc and c-fos oncogenes on Northern blot analysis. These observations show that because of subnormal activity of AdoMet synthetase, hypoxic liver is depleted of AdoMet, even when the animals are administered a complete diet. However, unlike rats on chronic lipotrope-deficient diets, hypoxic rats on a complete diet show no aberrant expression of oncogenes.

Interaction of tRNA (uracil-5-)-methyltransferase with NO2Ura-tRNA

tRNA in which uracil is completely replaced by 5-nitro-uracil was prepared by substituting 5-nitro-UTP for UTP in an in vitro transcription reaction. The rationale was that the 5-nitro substituent activates the 6-carbon of the Ura heterocycle towards nucleophiles, and hence could provide mechanism-based inhibitors of enzymes which utilize this feature in their catalytic mechanism. When assayed shortly after mixing, the tRNA analog, NO2Ura-tRNA, is a potent competitive inhibitor of tRNA-Ura methyl transferase (RUMT). Upon incubation, the analog causes a time-dependent inactivation of RUMT which could be reversed by dilution into a large excess of tRNA substrate. Covalent RUMT-NO2Ura-tRNA complexes could be isolated on nitrocellulose filters or by SDS-PAGE. The interaction of RUMT and NO2Ura-tRNA was deduced to involve formation of a reversible complex, followed by formation of a reversible covalent complex in which Cys 324 of RUMT is linked to the 6-position of NO2Ura 54 in NO2Ura-tRNA.

Enzymatic formation of modified nucleosides in tRNA: dependence on tRNA architecture

Information is still quite limited concerning the structural requirements in tRNA molecules for their post-transcriptional maturation by base and ribose modification enzymes. To address this question, we have chosen as the model system yeast tRNAAsp that has a known three-dimensional structure and the in vivo modifying machinery of the Xenopus laevis oocyte able to act on microinjected tRNA precursors. We have systematically compared the modification pattern of wild-type tRNAAsp with that of a series of structural mutants (21 altogether) altered at single or multiple positions in the D-, T-and the anticodon branch, as well as in the variable region. The experimental system allowed us to analyze the effects of structural perturbations in tRNA on the enzymatic formation of modified nucleosides at 12 locations scattered over the tRNA cloverleaf. We found that the formation of m1G37 and psi 40 in the anticodon loop and stem and psi 13 in the D-stem, were extremely sensitive to 3D perturbations. In contrast, the formation of T54, psi 55 and m1A58 in the T-loop, m5C49 in the T-stem and m2G6 in the amino acid accepting stem were essentially insensitive to change in the overall tRNA architecture; these modified nucleosides were also formed in appropriate minimalist (stems and loops) tRNA domains. The formation of m2G26 at the junction between the anticodon and the D-stem, of Q34 and manQ34 in the anticodon loop were sensitive only to drastic structural perturbation of the tRNA. Altogether, these results reflect the existence of different modes of tRNA recognition by the many different modifying enzymes. A classification of this family of maturation enzymes into two major groups, according to their sensitivities to structural perturbations in tRNA, is proposed.

A correlation between N2-dimethylguanosine presence and alternate tRNA conformers

Even though the evolutionary conservation of the cloverleaf model is strongly suggestive of powerful constraints on the secondary structure of functional tRNAs, some mitochondrial tRNAs cannot be folded into this form. From the optimal base pairing pattern of these recalcitrant tRNAs, structural correlations between the length of the anticodon stem and the lengths of connector regions between the two helical domains, formed by the coaxial stacking of the anticodon and D-stems and the acceptor and T-stems, have been derived and used to scan the tRNA and tRNA gene database. We show here that some cytosolic tRNA gene sequences that are compatible with the cloverleaf model can also be folded into patterns proposed for the unusual mitochondrial tRNAs. Furthermore, the ability to be folded into these atypical structures correlates in the mature RNA sequences with the presence of dimethylguanosine, whose role may be to prevent the unusual mitochondrial tRNA pattern folding.

Stereochemistry of tRNA(m5U54)-methyltransferase catalysis: 19F NMR spectroscopy of an enzyme-FUraRNA covalent complex

The catalytic mechanism of tRNA(m5U54)-methyltransferase (RUMT) involves the formation of a covalent adduct between Cys324 of RUMT and C6 of Ura54 in tRNA. The covalent adduct is subsequently methylated at C5 by S-adenosyl-L-methionine (AdoMet). We used an RNA substrate analog containing 5-fluorouracil (FUra) in place of Ura54 to trap the covalent complex and analyzed the adduct by 19F NMR spectroscopy. The 19F NMR spectrum of the adduct consisted of an overlapping doublet of quartets, with an H6-F coupling constant of 4 Hz and a CH3-F coupling constant of 22.4 Hz. On the basis of the magnitude of the H6-F coupling constant, we determined that Cys324 of RUMT and the methyl moiety from AdoMet added across the 5,6-double bond of FUra54 in cis fashion. We deduced that the nucleophilic addition was also cis in the normal enzymatic reaction and that the subsequent beta-elimination of the 5-H and catalytic cysteine was trans. Further, on the basis of chemical considerations, we proposed several conformational adaptations of enzyme-substrate complexes that must occur on the reaction pathway. Together with previous studies, this study enables the proposal of the complete stereochemical pathway for the RUMT-catalyzed methylation of Ura54 in tRNA.

Location of N2,N2-dimethylguanosine-specific tRNA methyltransferase

Most steps in the maturation of nuclear coded tRNAs occur in the nucleus in eukaryotic cells, but little is known as to the intranuclear location of this RNA maturation pathway. Indirect immunofluorescence experiments using antibody to N2,N2 dimethylguanosine-specific tRNA methyltransferase, a tRNA processing enzyme, and to Nup1p, a nuclear pore protein, show that both locate to the nuclear periphery in wild type cells. Staining of the nuclear membrane is more uniform with anti-Trm1p than the punctate staining observed with antibodies recognizing Nup1p. Biochemical fractionation experiments comparing fractionation of Trm1p with Nup1p, tRNA splicing ligase, and tRNA splicing endonuclease show that Trm1p behaves more like the known peripheral nuclear membrane proteins, Nup1p and tRNA splicing ligase, than like the integral membrane protein, tRNA splicing endonuclease. Cells overproducing Trm1p also concentrate it to the nuclear periphery. Thus, the site(s) of interaction of Trm1p are not easily saturable and are likely to be in excess to Trm1p. Trm1p is shared by mitochondria and the nucleus. Cells transformed with a gene coding Trm1p with a mutant nuclear targeting signal display cytoplasmic staining and an enzyme with increased solubility when compared to the solubility of wild type enzyme. Thus, mutations that prevent the enzyme from entering the nucleus result in an increase in its cytosolic but not mitochondrial concentration suggesting that the mitochondrial/nuclear distribution of Trm1p is not due solely to competition of mitochondrial and nuclear targeting information.

tRNA-m1G methyltransferase interactions: touching bases with structure

m1G methyltransferase of Escherichia coli is being examined with regard to how specific tRNA substrates are recognized. This enzyme appears to require the entire tRNA structure of optimal activity. Recognition may require specific base contacts as well as phosphate backbone structures embodied in the tRNA structure.

Enzymatic formation of N2,N2-dimethylguanosine in eukaryotic tRNA: importance of the tRNA architecture

In eukaryotic tRNA, guanosine at position 26 in the junction between the D-stem and the anticodon stem is mostly modified to N2,N2-dimethylguanosine (m2(2)G26). Here we review the available information on the enzyme catalyzing the formation of this modified nucleoside, the SAM-dependent tRNA (m2(2)G26)-methyltransferase, and our attemps to identify the parameters in tRNA needed for efficient enzymatic dimethylation of guanosine-26. The required identity elements in yeast tRNA for dimethylation under in vitro conditions by the yeast tRNA(m2(2)G26)-methyltransferase (the TRM1 gene product) are comprised of two G-C base pairs at positions G10-C25 and C11-G24 in the D-stem together with a variable loop of at least five nucleotides. These positive determinants do not seem to act via base specific interactions with the methyltransferase; they instead ensure that G26 is presented to the enzyme in a favorable orientation, within the central 3D-core of the tRNA molecule. The anticodon stem and loop is not involved in such an interaction with the enzyme. In a heterologous in vivo system, consisting of yeast tRNAs microinjected into Xenopus laevis oocytes, the requirements for modification of G26 are less stringent than in the yeast homologous in vitro system. Indeed, G26 in several microinjected tRNAs becomes monomethylated, while in yeast extracts it stays unmethylated, even after extensive incubation. Thus either the X laevis tRNA(m2(2)G26)-methyltransferase has a more relaxed specificity than its yeast homolog, or there exist two distinct G26-methylating activities, one for G26-monomethylation, and one for dimethylation of G26.(ABSTRACT TRUNCATED AT 250 WORDS)

Structural elements in yeast tRNAs required for homologous modification of guanosine-26 into dimethylguanosine-26 by the yeast Trm1 tRNA-modifying enzyme

In eukaryotic tRNAs, guanosines in position 26 (G26), located at the junction between the D-stem and the anticodon stem of tRNA, are usually modified to N2,N2-dimethylguanosine (m2(2)G). Although G26 is a prerequisite for biosynthesis of m2(2)G26, it is not self-sufficient for the formation of the dimethylated G26, since in exceptional cases eukaryotic tRNAs have an unmodified G26. In the yeast Saccharomyces cerevisiae the only tRNA species with an unmodified G26 is tRNAAsp. Using in vitro transcripts of this tRNA, as well as of yeast tRNAPhe, a tRNA containing m2(2)G26 in vivo, we have investigated the requirements on tRNA sequences and structures for the formation of m2(2)G26 by the yeast enzyme, i.e. in a homologous in vitro system. We have now demonstrated that G26 was efficiently dimethylated in vitro also after deletion of the entire anticodon stem and loop. We conclude that the elements necessary for a productive interaction between G26 in nuclear coded yeast tRNAs and the yeast G26 modifying enzyme are located within the core of the tRNA. For modification of G26 to m2(2)G26 via monomethylated G26, important primary and secondary structural elements in the tRNAs are a size of at least five nucleotides in the variable loop together with two G-C base pairs in the D-stem. This is the first case reported where the minimal requirements on nuclear coded tRNAs for a yeast modifying enzyme has been elucidated.

Substrate specificity of tRNA (adenine-1-)-methyltransferase from Thermus thermophilus HB27

tRNA (adenine-1-)-methyltransferase was purified to homogeneity from an extreme thermophile, Thermus thermophilus HB27, by several steps of column chromatographies. The molecular weight of this enzyme was about 60,000 as analyzed by SDS polyacrylamide gel electrophoresis. Km for E. coli tRNA(2Glu) was 100 nM and that for the methyl group donor, S-adenosyl-L-methionine, was 7.8 microM. The substrate specificity of the enzyme was investigated by using T7 RNA polymerase transcripts and tRNA fragments obtained by partial digestion with RNases. The enzyme was able to transfer the methyl group to the 3'-half fragment of E. coli initiator tRNA, however, the extent of methylation was elevated by more than five times when the 5'-half fragment was added and annealed to the 3'-half. This indicates that the main recognition site of the enzyme is within the 3'-half region of tRNA molecule, while the tertiary interaction between the T-loop and the D-loop is very effective for the adequate methylation reaction.

In vitro methylation of Escherichia coli 16S rRNA by tRNA (m5U54)-methyltransferase

16S rRNA, isolated from Escherichia coli or synthesized in vitro, is methylated by tRNA (m5U54)-methyltransferase (RUMT) and S-adenosyl-L-methionine to give ribothymidine (m5U). By methylation studies of 16S rRNA fragments, nearest-neighbor analysis, and nuclease protection experiments, the site of methylation was identified as U788. We have previously shown that the substrate consensus sequence for the T-arm of tRNA consists of a 2-5 base-pair stem and a 7-base loop, with certain constraints on base substitutions within the loop, and in the first two bases which close the loop [Gu, X., & Santi, D. V. (1991) Biochemistry 30, 2999-3002]. U788 of 16S rRNA is within a 9-base loop of a predicted stem-loop structure of 16S rRNA. If Ado substitution is allowed at the third and seventh positions of the loop and the first and ninth bases of the loop form an A-C base pair, the resulting stem-loop falls within the RUMT consensus sequence of the T-arm of tRNA. Individual mutants of the tRNA T-arm at these positions confirm that the substitutions are allowable, and expand the previous consensus sequence. Further, prevention of 7-base loop formation by requiring C-C base-pair formation at the loop closure abolishes substrate activity. RUMT forms a complex with Syn 16S rRNA which can be isolated on nitrocellulose filters or by SDS-PAGE electrophoresis. The enzyme also catalyzes exchange of tritium of [3H]Ura-16S rRNA for protons of water. By analogy with studies with tRNA [Gu, X., & Santi, D. V. (1991) Biochemistry 31, 10295-10302], the mechanism of methylation is proposed to involve formation of a covalent, albeit reversible, Michael adduct with the target U788 of 16S rRNA.

Aminoacyl-tRNA synthetase and U54 methyltransferase recognize conformations of the yeast tRNA(Phe) anticodon and T stem/loop domain

The enzyme-catalyzed posttranscriptional modification of tRNA and the contributions of modified nucleosides to tRNA structure and function can be investigated with chemically synthesized domains of the tRNA molecule. Heptadecamer RNAs with and without modified nucleosides and DNAs designed as analogs to the anticodon and T stem/loop domains of yeast tRNA(Phe) were produced by automated chemical synthesis. The unmodified T stem/loop domain of yeast tRNA(Phe) was a substrate for the E coli m5U54-tRNA methyltransferase activity, RUMT. Surprisingly, the DNA analog of the T stem/loop domain composed of d(A,U,G,C) was also a substrate. In addition, the DNA analog inhibited the methylation of unfractionated, undermodified E coli tRNA lacking the U54 methylation. RNA anticodon domains and DNA analogs differentially and specifically affected aminoacylation of the wild type yeast tRNA(Phe). Three differentially modified tRNA(Phe) anticodon domains with psi 39 alone, m1G37 and m5C40, or psi 39 with m1G37 and m5C40,stimulated phenylalanyl-tRNA synthetase (FRS) activity. However, one anticodon domain, with m5C40 as the only modified nucleoside and a closed loop conformation, inhibited FRS activity. Modified and unmodified DNA analogs of the anticodon, tDNA(PheAC), inhibited FRS activity. Analysis of the enzyme activity in the presence of the DNA analog characterized the DNA/enzyme interaction as either partial or allosteric inhibition. The disparity of action between the DNA and RNA hairpins provides new insight into the potential allosteric relationship of anticodon binding and open loop conformational requirements for active site function of FRS and other aaRSs. The comparison of the stimulatory and inhibitory properties of variously modified RNA domains and DNA analogs demonstrates that conformation, in addition to primary sequence, is important for tRNA-protein interaction. The enzyme recognition of various DNA analogs as substrate and/or inhibitors of activity demonstrates that conformational determinants are not restricted to ribose and the standard A-form RNA structure.

Enzymatic mechanism of tRNA (m5U54)methyltransferase

tRNA (m5U54)methyltransferase (RUMT) catalyzes the methylation of uridine 54 of transfer RNA by S-adenosyl-L-methionine. In this report, we present the enzymatic mechanism of RUMT, including the stereochemical course of the methylation reaction, and discuss RUMT-tRNA recognition. As part of its enzymatic mechanism, we postulate that RUMT catalyzes the disruption of RNA-RNA contacts. We also show that many nucleotide substitutions can be made in the T-loop of tRNA without affecting RUMT binding, indicating that the recognition of the T-loop by RUMT is not stringent.

The tRNA-(m5U54)-methyltransferase of Escherichia coli is present in two forms in vivo, one of which is present as bound to tRNA and to a 3'-end fragment of 16 S rRNA

The enzyme tRNA-(m5U54)-methyltransferase (EC 2.1.1.35) of Escherichia coli catalyzes the transfer of a methyl group from S-adenosyl-L-methionine to uridine in position 54 of the T psi-loop of all E. coli tRNA species, forming 5-methyluridine (m5U). In vivo, this enzyme is present both as a native polypeptide of 42 kDa and as a TrmA.RNA complex. The TrmA.RNA complex is not dissociated during strong denaturing conditions such as boiling in 8 M urea or 6 M guanidine HCl, consisting with that the RNA is covalently bound to the protein. After sequencing and Southern blot analyses, the RNA was identified to be a subset of undermodified tRNA species as well as the 3' terminus of 16 S rRNA. However, the complex is not associated with the ribosome and the covalently bound RNA does not affect the tRNA methylating activity of the enzyme.

Identity elements for N2-dimethylation of guanosine-26 in yeast tRNAs

N2,N2-dimethylguanosine (m2(2)G) is a characteristic nucleoside that is found in the bend between the dihydro-uridine (D) stem and the anticodon (AC) stem in over 80% of the eukaryotic tRNA species having guanosine at position 26 (G26). However, since a few eukaryotic tRNAs have an unmodified G in that position, G26 is a necessary but not a sufficient condition for dimethylation. In yeast tRNA(Asp) G26 is unmodified. We have successively changed the near surroundings of G26 in this tRNA until G26 became modified to m2(2)G by a tRNA(m2(2)G26)methyltransferase in Xenopus laevis oocytes. In this way we have identified the two D-stem basepairs C11-G24, G10-C25 immediately preceding G26 as major identity elements for the dimethylating enzyme modifying G26. Furthermore, increasing the extra loop in tRNA(Asp) from four to the more usual five bases influenced the global structure of the tRNA such that the m2(2)G26 formation was drastically decreased even if the near region of G26 had the two consensus basepairs. We conclude that not only are the two consensus base pairs in the D-stem a prerequisite for G26 modification, but also is any part of the tRNA molecule that influence the 3D-structure important for the recognition between nuclear coded tRNAs and the tRNA(m2(2)G26)methyltransferase.

Separate information required for nuclear and subnuclear localization: additional complexity in localizing an enzyme shared by mitochondria and nuclei

The TRM1 gene of Saccharomyces cerevisiae codes for a tRNA modification enzyme, N2,N2-dimethylguanosine-specific tRNA methyltransferase (m2(2)Gtase), shared by mitochondria and nuclei. Immunofluorescent staining at the nuclear periphery demonstrates that m2(2)Gtase localizes at or near the nuclear membrane. In determining sequences necessary for targeting the enzyme to nuclei and mitochondria, we found that information required to deliver the enzyme to the nucleus is not sufficient for its correct subnuclear localization. We also determined that mislocalizing the enzyme from the nucleus to the cytoplasm does not destroy its biological function. This change in location was caused by altering a sequence similar to other known nuclear targeting signals (KKSKKKRC), suggesting that shared enzymes are likely to use the same import pathway as proteins that localize only to the nucleus. As with other well-characterized mitochondrial proteins, the mitochondrial import of the shared methyltransferase depends on amino-terminal amino acids, and removal of the first 48 amino acids prevents its import into mitochondria. While this truncated protein is still imported into nuclei, the immunofluorescent staining is uniform throughout rather than at the nuclear periphery, a staining pattern identical to that described for a fusion protein consisting of the first 213 amino acids of m2(2)Gtase in frame with beta-galactosidase. As both of these proteins together contain the entire m2(2)Gtase coding region, the information necessary for association with the nuclear periphery must be more complex than the short linear sequence necessary for nuclear localization.

Covalent adducts between tRNA (m5U54)-methyltransferase and RNA substrates

The interaction of tRNA (m5U54)-methyltransferase (RUMT) with in vitro synthesized unmodified tRNA and a 17-base oligoribonucleotide analog of the T-arm of tRNA in the absence of AdoMet has been investigated. Binary complexes are formed which are isolable on nitrocellulose filters and are composed of noncovalent and covalent complexes in nearly equal amounts. The covalent RUMT-RNA complexes are stable to SDS-PAGE and migrate slower than free enzyme or RNA. Kinetic and thermodynamic constants involved in formation and disruption of noncovalent and covalent binary complexes have been determined and interpreted in the context of steady-state kinetic parameters of the enzyme-catalyzed methylation and 5-H exchange of substrate. The results show that the isolable covalent complex is kinetically incompetent as an intermediate for methylation. Isotope trapping experiments show that when AdoMet is added to preformed binary complex, all bound tRNA is converted to methylated product; thus, the covalent complexes are chemically competent to form products. We have concluded that, after a reversible binary complex is formed, the catalytic thiol adds to the 6-carbon of the U54 of tRNA. The initial adduct leaves the reaction pathway to protonation at carbon 5; the latter can deprotonate and re-enter the pathway to form methylated product. It is speculated that covalent binary RUMT-RNA adducts may serve as depots of enzyme-tRNA complexes primed for methylation, or in unknown roles with RNAs other than tRNA.

Structural requirements for tRNA methylation. Action of Escherichia coli tRNA(guanosine-1)methyltransferase on tRNA(1Leu) structural variants

The Escherichia coli enzyme tRNA(m1G)methyltransferase, one of a group of post-transcription tRNA-modifying enzymes, shows remarkable specificity in selecting the tRNA species and the specific guanosine base to be methylated. To examine the structural basis of this specificity, we synthesized a total of 15 modifications of tRNA(1Leu) and measured their methylation reaction kinetics in vitro. Elimination of any one of the three tRNA side loops, the V loop, the T loop, or the D loop, reduced the Vmax for methylation by about 1 order of magnitude. Elimination of all three side loops reduced Vmax by about 2 orders of magnitude. Clearly, gross tRNA structure is important for full enzyme activity. At the bottom of the stem proximal to the anticodon loop, in the pair at positions 31-39, substitution of a G-C for a C-G, a change that should not weaken the helical structure, had little effect on Vmax or Km. However, substitution of a G for a C increased Vmax and Km, whereas substitution of a C for G sharply reduced Vmax and, to a lesser extent, Km. These results appear to be a consequence of the principle that purines are better than pyrimidines in the stacking of adjacent bases for stability. Stacking in the stem structure appears to be important for methylation enzyme activity. In the anticodon loop itself, changing a U to a C had little effect, but changing the G of the anticodon to a C reduced Vmax over 20-fold, demonstrating the importance of the presence of the anticodon G adjacent to the G being methylated for enzyme recognition.

Theoretical mechanisms for synthesis of carcinogen-induced embryonic proteins: XXVI. Evolutionary significance of carcinogen-induced embryonic gene activity

Besides the major theme of this series of writings--that chemically derepressed embryonic genes are fundamental to the mechanisms of carcinogenesis, there appear to be other significant aspects to this process. Yeast cells have the ability to differentially respond to carcinogens and non-carcinogens by the activation of embryonic type genes that are also found in mammals. This strange relationship is interpreted here as being due to certain phylogetically conserved genes from yeasts existing also in mammals that are used in both organisms for the same process. For example, a protooncogene found in yeast cells or embryonic cells serves for rapid mitosis. Also yeast mating type genes have high homologies to homeotic domains and therefore may be prototype genes of homeotic genes, which are embryonic type genes in animals.

The gene for a tRNA modifying enzyme, m5U54-methyltransferase, is essential for viability in Escherichia coli

One of the most abundant modified nucleosides in tRNA is 5-methyluridine (m5U or rT, ribothymidine). The enzyme tRNA(m5U54)methyltransferase [S-adenosyl-L-methionine:tRNA (uracil-5-)-methyltransferase, EC 2.1.1.35] (the trmA gene product) catalyzes S-adenosylmethionine-dependent methylation of the uracil in position 54 (T psi C loop) in all Escherichia coli tRNAs to form m5U. Hitherto no modified nucleoside in tRNA has been shown to be essential for growth, although their importance in fine tuning the function of tRNA is well established. In this paper, we show that the structural gene trmA is essential for viability, although the known catalytic activity of the tRNA(m5U54)methyltransferase is not.

Stereochemistry of methyl transfer catalyzed by tRNA (m5U54)-methyltransferase--evidence for a single displacement mechanism

tRNA (m5U54)-methyltransferase (RUMT) catalyzes the transfer of a methyl group from S-adenosyl-L-methionine (AdoMet) to the 5-carbon of uridine 54 of tRNA. We have determined the steric course of methyl transfer, using (methyl-R)- and (methyl-S)-[methyl-2H1,3H]-AdoMet as the chiral methyl donors, and tRNA lacking the 5-methyl group at position 54 as the acceptor. Following methyl transfer, ribothymidine was isolated and degraded to chiral acetic acid for configurational analysis. Transfer of the chiral methyl group to U54 proceeded with inversion of configuration of the chiral methyl group, suggesting that RUMT catalyzed methyl transfer occurs by a single SN2 displacement mechanism.

The absence of modified nucleotides affects both in vitro assembly and in vitro function of the 30S ribosomal subunit of Escherichia coli

16S RNA of Escherichia coli lacking all post-transcriptional modifications and with 5'-termini of pppGGGAGA-, pppGAA-, pppAAA-, and pAAA- were prepared by in vitro transcription of appropriately engineered plasmids with T7 or SP6 RNA polymerases. These synthetic versions of 16S RNA were compared with natural 16S RNA for their ability to reconstitute 30S ribosomal subunits in vitro using varied conditions for both the isolation of the RNA and for reconstitution. Under all conditions studied, natural 16S RNA assembled correctly, as judged by velocity centrifugation comparison with an internal standard of native 30S particles, and the recovered ribosomes were 80-100% as active as native 30S ribosomes in initiation complex formation, P site binding of AcVal-tRNA, A site binding of Phe-tRNA, and formation of the first peptide bond. In contrast, all of the synthetic constructs including pAAA-, which has the same sequence as native 16S RNA, were only partially active in reconstitution and in the functional assays. We conclude that the lack of the 10 methylated nucleotides and/or the 2 pseudouridylate residues present in natural 16S RNA must be responsible for the reduced activity of the synthetic RNAs in ribosome assembly and function.

The T-arm of tRNA is a substrate for tRNA (m5U54)-methyltransferase

Fragments of Escherichia coli FUra-tRNA(1Val) as small as 15 nucleotides form covalent complexes with tRNA (m5U54)-methyltransferase (RUMT). The sequence essential for binding includes position 52 of the T-stem and the T-loop and extends toward the 3' acceptor end of FUra-tRNA. The in vitro synthesized 17mer T-arm of E. coli tRNA(1Val), composed of the seven-base T-loop and 5-base-pair stem, is a good substrate for RUMT. The Km is decreased 5-fold and kcat is decreased 2-fold compared to the entire tRNA. The T-arm structure could be further reduced to an 11mer containing the loop and two base pairs and still retain activity; the Km was similar to that of the 17mer T-arm, whereas kcat was decreased an additional 20-fold. The data indicate that the primary specificity determinants for the RUMT-tRNA interaction are contained within the primary and secondary structure of the T-arm of tRNA.

Both amino acid changes in nsP1 of Sindbis virusLM21 contribute to and are required for efficient expression of the mutant phenotype

SVLM21 is a mutant of Sindbis virus which in contrast to the standard virus, SVSTD, is able to replicate in Aedes albopictus mosquito cells deprived of methionine. Previously, by making use of the infectious Toto plasmids, we had constructed recombinant viruses containing various SVLM21 sequences, and were thereby able to map the mutations associated with the SVLM21 phenotype to the gene for the nonstructural protein nsP1. Two mutations were found in the nsP1 gene of SVLM21. These led to predicted amino acid changes at residue 87 from Arg to Leu, and at residue 88 from Ser to Cys. In the work presented here, we assess the relative contributions of these two mutations to the SVLM21 phenotype using site-directed mutagenesis to obtain virus encoding only the change to Leu at residue 87 of nsP1 (SVMS319), or only the change to Cys at residue 88 (SVMS321). In addition we show that SVLM10, which was isolated during the selection procedure for SVLM21, encodes only the change at residue 88. In addition to its ability to grow in methionine-deprived mosquito cells, SVLM21 differs from SVSTD in two other respects: (1) it shows an increased sensitivity to neplanocin A (NPA) and (2) it generates increased levels of methyltransferase in infected cells. Whether we looked at resistance to low methionine, sensitivity to NPA, or levels of methyltransferase generated, SVMS319, SVMS321, and SVLM10 all expressed only a partial SVLM21 phenotype. Furthermore we were not able in these experiments to distinguish between these three viruses. We conclude therefore that both amino acid changes, i.e., at residues 87 and 88, are required to produce the full SVLM21 phenotype, and that both changes contribute equally.

SVLM21, a Sindbis virus mutant resistant to methionine deprivation, encodes an altered methyltransferase

The replication of Sindbis virus (SVSTD) in cultured Aedes albopictus mosquito cells is sensitive to methionine deprivation. We have suggested from earlier work that this sensitivity is primarily because of a decreased pool of S-adenosyl methionine (ado met) and the resultant failure to methylate the 5' cap of the viral mRNAs. SVLM21, a strain of Sindbis virus derived in our laboratory from SVSTD by serial passage on mosquito cells maintained after infection in low concentrations of methionine, is resistant to methionine starvation. It was proposed that this adaptation to low methionine, and to the resultant low intracellular levels of ado met, reflected the accumulation of mutations which led to the generation of a viral RNA cap methyltransferase with an increased affinity for ado met. We report here kinetic data which distinguished the enzymes coded for by SVSTD and SVLM21. Using guanylylimidodiphosphate (GIDP) as the methyl acceptor, radioactively labeled ado met as the methyl donor, and lysates from infected BHK cells as the enzyme source, we calculated from our results that SVLM21 generated a methyltransferase with a Km for ado met 10-fold lower than that generated by either SVSTD or the related alphavirus, Semliki Forest virus. In addition, we found that BHK cells infected with SVLM21 generated higher levels of methyltransferase activity than did cells infected with SVSTD and that the SVSTD and SVLM21 enzymes differed with respect to their relative activities at elevated temperatures. We conclude from these results that the SVLM21 phenotype is associated with an altered methyltransferase and suggest that this is the basis of the resistance of SVLM21 to methionine deprivation.

Effects of modification of 4-thiouridine in E. coli tRNA(fMet) on its methyl acceptor activity by thermostable Gm-methylases

tRNA(guanosine-2'-)-methyltransferases (Gm-methylases) isolated from extreme thermophiles, Thermus thermophilus strains HB 27 and HB 8, methylate the 2'-OH of the G18 ribose of the GG sequence in the D loop of tRNA, by recognizing the D "loop-stem" structure as a minimal requirement. To examine the role of the consensus uridine residue at position 8 (U8) adjacent to the D "loop-stem" region in the recognition of Gm-methylase, 4-thiouridine at this position (s4U8) in Escherichia coli tRNAfMet was modified reversibly with S-benzylthioisothiourea (sBTIU) or irreversibly by UV light. The initial velocities of the methylation reaction for the sBTIU-modified and the UV-induced cross-linked tRNAs were decreased to 40 and 30%, respectively, of that of the intact tRNA, but the sBTIU-modified tRNA regained almost full activity on reduction with beta-mercaptoethanol. Although both of the modified tRNAfMetS showed larger Km (although to different extents) and slightly smaller Vmax than the intact tRNAfMet, they retained full activities of methylation with tRNA(adenine-1-)-methyltransferase (m1A-methylase) and of aminoacylation with aminoacyl-tRNA synthetase (ARS) fraction as well, both of which were prepared from T. thermophilus strain HB 27. The 5'-half fragments derived from the sBTIU-modified and cross-linked tRNAfMetS showed methylation efficiency (Vmax/Km) not appreciably different from that of the unmodified 5'-half fragment. These results suggest that the conformation of S4U8 residue of tRNA is deeply involved in the recognition of tRNA by Gm-methylase.

Amino-terminal extension generated from an upstream AUG codon increases the efficiency of mitochondrial import of yeast N2,N2-dimethylguanosine-specific tRNA methyltransferases

Fusions between the TRM1 gene of Saccharomyces cerevisiae and COXIV or DHFR were made to examine the mitochondrial targeting signals of N2,N2-dimethylguanosine-specific tRNA methyltransferase [tRNA (m2(2)G)dimethyltransferase]. This enzyme is responsible for the modification of both mitochondrial and cytoplasmic tRNAs. We have previously shown that two forms of the enzyme are translated from two in-frame ATGs in this gene, that they differ by a 16-amino-acid amino-terminal extension, and that both the long and short forms are imported into mitochondria. Results of studies to test the ability of various TRM1 sequences to serve as surrogate mitochondrial targeting signals for passenger protein import in vitro and in vivo showed that the most efficient signal derived from tRNA (m2(2)G)dimethyltransferase included a combination of sequences from both the amino-terminal extension and the amino terminus of the shorter form of the enzyme. The amino-terminal extension itself did not serve as an independent mitochondrial targeting signal, whereas the amino terminus of the shorter form of tRNA (m2(2)G)dimethyltransferase did function in this regard, albeit inefficiently. We analyzed the first 48 amino acids of tRNA (m2(2)G)dimethyltransferase for elements of primary and secondary structure shared with other known mitochondrial targeting signals. The results lead us to propose that the most efficient signal spans the area around the second ATG of TRM1 and is consistent with the idea that there is a mitochondrial targeting signal present at the amino terminus of the shorter form of the enzyme and that the amino-terminal extension augments this signal by extending it to form a larger, more efficient mitochondrial targeting signal.