miR-34a directly targets tRNAiMet precursors and affects cellular proliferation, cell cycle, and apoptosis.

It remains unknown whether microRNA (miRNA/miR) can target transfer RNA (tRNA) molecules. Here we provide evidence that miR-34a physically interacts with and functionally targets tRNAiMet precursors in both in vitro pulldown and Argonaute 2 (AGO2) cleavage assays. We find that miR-34a suppresses breast carcinogenesis, at least in part by lowering the levels of tRNAiMet through AGO2-mediated repression, consequently inhibiting the proliferation of breast cancer cells and inducing cell cycle arrest and apoptosis. Moreover, miR-34a expression is negatively correlated with tRNAiMet levels in cancer cell lines. Furthermore, we find that tRNAiMet knockdown also reduces cell proliferation while inducing cell cycle arrest and apoptosis. Conversely, ectopic expression of tRNAiMet promotes cell proliferation, inhibits apoptosis, and accelerates the S/G2 transition. Moreover, the enforced expression of modified tRNAiMet completely restores the phenotypic changes induced by miR-34a. Our results demonstrate that miR-34a directly targets tRNAiMet precursors via AGO2-mediated cleavage, and that tRNAiMet functions as an oncogene, potentially representing a target molecule for therapeutic intervention.

Drosophila RNA polymerase III repressor Maf1 controls body size and developmental timing by modulating tRNAiMet synthesis and systemic insulin signaling.

The target-of-rapamycin pathway couples nutrient availability with tissue and organismal growth in metazoans. The key effectors underlying this growth are, however, unclear. Here we show that Maf1, a repressor of RNA polymerase III-dependent tRNA transcription, is an important mediator of nutrient-dependent growth in Drosophila. We find nutrients promote tRNA synthesis during larval development by inhibiting Maf1. Genetic inhibition of Maf1 accelerates development and increases body size. These phenotypes are due to a non-cell-autonomous effect of Maf1 inhibition in the fat body, the main larval endocrine organ. Inhibiting Maf1 in the fat body increases growth by promoting the expression of brain-derived insulin-like peptides and consequently enhanced systemic insulin signaling. Remarkably, the effects of Maf1 inhibition are reproduced in flies carrying one extra copy of the initiator methionine tRNA, tRNA(i)(Met). These findings suggest the stimulation of tRNA(i)(Met) synthesis via inhibition of dMaf1 is limiting for nutrition-dependent growth during development.

Construction of modified ribosomes for incorporation of D-amino acids into proteins.

While numerous biologically active peptides contain D-amino acids, the elaboration of such species is not carried out by ribosomal synthesis. In fact, the bacterial ribosome discriminates strongly against the incorporation of D-amino acids from D-aminoacyl-tRNAs. To permit the incorporation of D-amino acids into proteins using in vitro protein-synthesizing systems, a strategy has been developed to prepare modified ribosomes containing alterations within the peptidyltransferase center and helix 89 of 23S rRNA. S-30 preparations derived from colonies shown to contain ribosomes with altered 23S rRNAs were found to exhibit enhanced tolerance for D-amino acids and to permit the elaboration of proteins containing D-amino acids at predetermined sites. Five specific amino acids in Escherichia coli dihydrofolate reductase and Photinus pyralis luciferase were replaced with D-phenylalanine and D-methionine, and the specific activities of the resulting enzymes were determined.

The chloroplast-derived trnW and trnM-e genes are not expressed in Arabidopsis mitochondria.

Depending on their genetic origin, plant mitochondrial tRNAs are classified into three categories: the "native" and "chloroplast-like" mitochondrial-encoded tRNAs and the imported nuclear-encoded tRNAs. The number and identity of tRNAs in each category change from one plant specie to another. As some plant mitochondrial trn genes were found to be not expressed, and as all Arabidopsis thaliana mitochondrial trn genes are known, we systematically tested the expression of A. thaliana mitochondrial trn genes. Both the "chloroplast-like" trnW and trnM-e genes were found to be not expressed. These exceptions are remarkable since trnW and trnM-e are expressed in the mitochondria of other land plants. Whereas we could not conclude which tRNA(Met) compensates the lack of expression of trnM-e, we showed that the cytosolic tRNA(Trp) is present in A. thaliana mitochondria, thus compensating the absence of expression of the mitochondrial-encoded trnW.

Importance of structural features for tRNA(Met) identity.

We showed previously that the tRNA tertiary structure makes an important contribution to the identity of yeast tRNA(Met) (Senger B, Aphasizhev R, Walter P, Fasiolo F, 1995, J Mol Biol 249:45-58). To learn more about the role played by the tRNA framework, we analyzed the effect of some phosphodiester cleavages and 2'OH groups in tRNA binding and aminoacylation. The tRNA is inactivated provided the break occurs in the central core region responsible for the tertiary fold or in the anticodon stem/loop region. We also show that, for tRNA(Met) to bind, the anticodon loop, but not the anticodon stem, requires a ribosephosphate backbone. A tertiary mutant of yeast tRNA(Met) involving interactions from the D- and T-loop unique to the initiator species fails to be aminoacylated, but still binds to yeast methionyl-tRNA synthetase. In the presence of 10 mM MgCl2, the mutant transcript has a 3D fold significantly stabilized by about 30 degrees C over a wild-type transcript as deduced from the measure of their T(m) values. The k(cat) defect of the tRNA(Met) mutant may arise from a failure to overcome an increase of the free energetic cost of distorting the more stable tRNA structure and/or a tRNA based MetRS conformational change required for formation of transition state of aminoacylation.

Use of a nonviral vector to express a chimeric tRNA-ribozyme against lymphocytic choriomeningitis virus: cytoplasmic accumulation of a catalytically competent transcript but minimal antiviral effect.

RNA polymerase III promoters direct the ubiquitous, high-level, expression of small, stable RNAs such as tRNAs, and thus are attractive candidates for achieving stable expression of small therapeutic (e.g., antiviral) molecules, such as ribozymes or antisense RNAs. In this article, we describe the use of a nonviral vector containing a tRNA promoter to express an antilymphocytic choriomeningitis virus (LCMV) ribozyme (tRNA-Rib5). The chimeric tRNA-ribozyme is specifically and efficiently transcribed by pol III in cell-free extracts, and the resulting transcript has appropriate ribozyme activity. In tissue culture studies, high levels of chimeric transcripts were readily detectable and were transported to the cytoplasm, the site of LCMV replication. Despite accumulation of tRNA-Rib5 in the cytoplasm of stably transformed cell clones, antiviral effects were minimal or absent. The implications of these findings and the potential use of this vector system for in vivo studies requiring the delivery of small molecules are discussed.

Yeast mitochondrial RNase P RNA synthesis is altered in an RNase P protein subunit mutant: insights into the biogenesis of a mitochondrial RNA-processing enzyme.

Rpm2p is a protein subunit of Saccharomyces cerevisiae yeast mitochondrial RNase P, an enzyme which removes 5' leader sequences from mitochondrial tRNA precursors. Precursor tRNAs accumulate in strains carrying a disrupted allele of RPM2. The resulting defect in mitochondrial protein synthesis causes petite mutants to form. We report here that alteration in the biogenesis of Rpm1r, the RNase P RNA subunit, is another consequence of disrupting RPM2. High-molecular-weight transcripts accumulate, and no mature Rpm1r is produced. Transcript mapping reveals that the smallest RNA accumulated is extended on both the 5' and 3' ends relative to mature Rpm1r. This intermediate and other longer transcripts which accumulate are also found as low-abundance RNAs in wild-type cells, allowing identification of processing events necessary for conversion of the primary transcript to final products. Our data demonstrate directly that Rpm1r is transcribed with its substrates, tRNA met f and tRNAPro, from a promoter located upstream of the tRNA met f gene and suggest that a portion also originates from a second promoter, located between the tRNA met f gene and RPM1. We tested the possibility that precursors accumulate because the RNase P deficiency prevents the removal of the downstream tRNAPro. Large RPM1 transcripts still accumulate in strains missing this tRNA. Thus, an inability to process cotranscribed tRNAs does not explain the precursor accumulation phenotype. Furthermore, strains with mutant RPM1 genes also accumulate precursor Rpm1r, suggesting that mutations in either gene can lead to similar biogenesis defects. Several models to explain precursor accumulation are presented.

In vivo deuteration of transfer RNAs: overexpression and large-scale purification of deuterated specific tRNAs.

Structural investigations of tRNA complexes using NMR or neutron scattering often require deuterated specific tRNAs. Those tRNAs are needed in large quantities and in highly purified and biologically active form. Fully deuterated tRNAs can be prepared from cells grown in deuterated minimal medium, but tRNA content under this conditions is low, due to regulation of tRNA biosynthesis in response to the slow growth of cells. Here we describe the large-scale preparation of two deuterated tRNA species, namely D-tRNAPhe and D-tRNAfMet (the method is also applicable for other tRNAs). Using overexpression constructs, the yield of specific deuterated tRNAs is improved by a factor of two to ten, depending on the tRNA and growth condition tested. The tRNAs are purified using a combination of classical chromatography on an anion exchange DEAE column with reversed phase preparative HPLC. Purification yields nearly homogenous deuterated tRNAs with a chargeability of 1400-1500 pmol amino acid/A260 unit. The deuterated tRNAs are of excellent biological activity.

Energy cost of translational proofreading in vivo. The aminoacylation of transfer RNA in Escherichia coli.

In many cases, the intrinsic binding energies of amino acids to aminoacyl-tRNA synthetases are inadequate to give the required accuracy of translation. This has necessitated the evolution of a second determinant of specificity, proofreading, or editing mechanisms that involve the expenditure of energy to remove errors. Studies of an error-editing function of bacterial methionyl-tRNA synthetase have led to the discovery of a distinct chemical mechanism of editing and to molecular dissection of the dual synthetic-editing function of the active site of the synthetase. Studies have also established the importance of proofreading in living cells and allowed direct measurements of energy costs associated with editing in vivo. An unexpected outcome of these studies was a discovery of functional and structural similarities between methionyl-tRNA synthetase and S-adenosylmethionine synthetase, suggesting an evolutionary relationship between the two proteins. The mechanism of editing involves a nucleophilic attack of a sulfur atom on the side chain of homocysteine in homocysteinyl adenylate on its carbonyl carbon, yielding homocysteine thiolactone. The model of the active site of methionyl-tRNA synthetase derived from structure-function studies explains how the active site partitions amino acids between synthetic and editing pathways. Hydrophobic and hydrogen bonding interactions of active site residues Trp305 and Tyr15 with the side chain of methionine prevent the cognate amino acid from entering the editing pathway. These interactions are missing in the case of the smaller side chain of the noncognate homocysteine, which therefore enters the editing pathway. Homocysteine thiolactone is formed as a result of editing of homocysteine by methionyl-tRNA synthetase in bacteria, yeast, and some cultured mammalian cells. In mammalian cells, enhanced synthesis of homocysteine thiolactone, is, thus far, associated with oncogenic transformation. In E. coli, most of the energy cost of proofreading by methionyl-tRNA synthetase is due to editing of the incorrect product, homocysteinyl adenylate.

Factor for inversion stimulation-dependent growth rate regulation of individual tRNA species in Escherichia coli.

We have studied the involvement of the factor for inversion stimulation (FIS) in the growth rate-dependent expression of the arginine, leucine, and methionine acceptor tRNA species. The concentration of individual tRNA species relative to 16 S rRNA was determined by blot hybridization using RNA preparations from bacteria with the fis gene deleted and from isogenic wild type bacteria. The RNA preparations were obtained from bacteria growing under steady state conditions in different media. The levels of tRNA(1Leu), tRNA(2Arg), tRNA(4Arg), and tRNA(5Arg decreased in the fis bacteria, relative to the wild type. The difference in levels increased with increasing growth rate. Surprisingly, tRNA(3Leu), tRNA(rMet), and tRNA(eMet) showed the opposite response, with an increase of the tRNA/16 S ratio in the fis bacteria. The tRNA(2Leu, tRNA(4Leu), tRNA(5Leu), and tRNA(3 Arg) had unaffected tRNA/16 S ratios in fis cells. We conclude that FIS, directly or indirectly, is involved in growth rate regulation of some tRNA species and that it affects the composition of the cellular tRNA pool.

Nuclear export of different classes of RNA is mediated by specific factors.

Various classes of RNA are exported from the nucleus to the cytoplasm, including transcripts of RNA polymerase I (large ribosomal RNAs), II (U-rich small nuclear RNAs [U snRNAs], mRNAs), and III (tRNAs, 5S RNA). Here, evidence is presented that some steps in the export of various classes of nuclear RNA are mediated by specific rather than common factors. Using microinjection into Xenopus oocytes, it is shown that a tRNA, a U snRNA, and an mRNA competitively inhibit their own export at concentrations at which they have no effect on the export of heterologous RNAs. While the export of both U snRNAs and mRNAs is enhanced by their 7-methyl guanosine cap structures, factors recognizing this structure are found to be limiting in concentration only in the case of U snRNAs. In addition to the specific factors, evidence for steps in the export process that may be common to at least some classes of RNA are provided by experiments in which synthetic homopolymeric RNAs are used as inhibitors.

Mapping the central fold of tRNA2(fMet) in the P site of the Escherichia coli ribosome.

4-Thiouridine (s4U), a photoreactive analog of uridine, was randomly incorporated into tRNA2(fMet) precursor molecules by transcription with T7 RNA polymerase. The s4U-containing transcripts were trimmed at their 5'-ends with RNase P RNA to yield mature tRNA2(fMet). The photoreactive tRNA2(fMet) derivatives were aminoacylated and bound to the P site of 70S ribosomes from Escherichia coli in the presence of a poly(A,G,U) template. Irradiation of the complexes at 300 nm resulted in the covalent cross-linking of tRNA2(fMet) to ribosomal proteins and rRNAs within both the 50S and 30S subunits. The labeled proteins were identified as L1, L27, and S19. 50S-subunit proteins L1 and L27 were attached to nucleotide U17 or U17.1 within the D loop of tRNA2(fMet), whereas 30S-subunit protein S19 was cross-linked to nucleotide U47 in the variable loop. Both of these sites occur in or near the central fold of the tRNA. These results permit us to map the D loop of P site-bound tRNA to the region between the central protuberance and the L1 ridge on the 50S ribosomal subunit, while the variable loop can be placed above the cleft on the head of the 30S subunit.

Ribozyme mediated destruction of RNA in vivo.

Previous studies have demonstrated that high ribozyme to substrate ratios are required for ribozyme inhibitory function in nuclear extracts. To obtain high intracellular levels of ribozymes, tRNA genes, known to be highly expressed in most tissues, have been modified for use as ribozyme expression cassettes. Ribozyme coding sequences were placed between the A and the B box, internal promoter sequences of a Xenopus tRNAMet gene. When injected into the nucleus of frog oocytes, the ribozyme tRNA gene (ribtDNA) produces 'hammerhead' ribozymes which cleave the 5' sequences of U7snRNA, its target substrate, with high efficiency in vitro. Oocytes were coinjected with ribtDNA, U7snRNA and control substrate RNA devoid of a cleavage sequence. It was found that the ribtRNA remained localized mainly in the nucleus, whereas the substrate and the control RNA exited rapidly into the cytoplasm. However, sufficient ribtRNA migrated into the cytoplasm to cleave, and destroy, the U7snRNA. Thus, the action of targeted 'hammerhead' ribozymes in vivo is demonstrated.

The independent regulation of tRNA(iMet) and tRNA(Asn) synthesis during Friend cell erythroid differentiation.

In this report, we have compared the changes in the production of tRNA(iMet) (initiator tRNA(Met] and tRNA(Asn), which occur during erythroid differentiation in the Friend erythroleukemia cell. The relative steady-state concentration of these two tRNAs (relative to the total tRNA population) was measured by aminoacylation. The results show that while the relative steady-state concentration of tRNA(iMet) changes very little in the cytoplasmic tRNA population, the relative concentration of tRNA(Asn) decreases during the first two days of differentiation and then undergoes an increase. This difference in the behavior of these two tRNAs is also seen when their relative concentrations in newly synthesized tRNA is examined. When tRNA is labeled with tritiated uridine for 24 h in vivo prior to isolation, the hybridization of this labeled tRNA to filter-bound tRNA genes shows that the relative concentration of tRNA(iMet) in newly synthesized tRNA changes very little, while the relative concentration of newly synthesized tRNA(Asn) again decreases through the first 2 days of differentiation, and then undergoes a smaller increase. Thus, the production of these two tRNAs appears to be independently regulated. Independent regulation of synthesis is also observed when examining the production of these two tRNAs in isolated nuclei. During erythroid differentiation, the relative synthesis of tRNA(iMet) (relative to total nuclear RNA synthesis) remains constant, while the relative synthesis of tRNA(Asn) undergoes periodic increases and decreases in value.