Highly charged radioactive initiator methionyl transfer RNA from in vivo labeled HeLa cells

³⁵S-Labeled Met-tRNA_f^Met can be prepared from HeLa cells, for studies of translation in vitro, with both a high degree of charging and a relatively high specific radioactivity. HeLa cells are labeled with [³⁵S]methionine in vivo, in the presence of cycloheximide to reduce translation. Their cytoplasmic RNA is then isolated by phenol extraction and subjected to cellulose ion-exchange chromatography in order to partially purify labeled Met-tRNA_f^Met and resolve it from Met-tRNA_m^Met.     

The efficiency of methionine incorporation from isoaccepting species of tRNAMet into rabbit globin in an homologous reticulocyte lysate system

Rabbit globin α and β chains were labeled with [³H]leucine, and with [³⁵S]methionine from reticulocyte tRNA^Met isoacceptors using a rabbit reticulocyte cell-free synthesis system. [³⁵S]Methionine from the three tRNA^Met species isolated by RPC-5 chromatography was incorporated into internal positions of both α and β globin. The initiator tRNA, tRNA^Met_I, exhibited very low efficiency for incorporating methionine internally, while tRNA^Met_II was four times more efficient than tRNA^Met_III. Amino acid analysis of the tryptic peptides of the labeled globins revealed that all three isoacceptors incorporated methionine into the normal methionine peptides. Similar studies with Escherichia coli [³⁵S]Met-tRNA^Met_f showed a 3-fold increase over the reticulocyte initiator tRNA in its capacity to incorporate methionine into the internal positions of rabbit globin.     

AIMP3/p18 Controls Translational Initiation by Mediating the Delivery of Charged Initiator tRNA to Initiation Complex

Aminoacyl-tRNA synthetase-interacting multifunctional proteins (AIMPs) are nonenzymatic scaffolding proteins that comprise multisynthetase complex (MSC) with nine aminoacyl-tRNA synthetases in higher eukaryotes. Among the three AIMPs, AIMP3/p18 is strongly anchored to methionyl-tRNA synthetase (MRS) in the MSC. MRS attaches methionine (Met) to initiator tRNA (tRNA_i^Met) and plays an important role in translation initiation. It is known that AIMP3 is dispatched to nucleus or nuclear membrane to induce DNA damage response or senescence; however, the role of AIMP3 in translation as a component of MSC and the meaning of its interaction with MRS are still unclear. Herein, we observed that AIMP3 specifically interacted with Met-tRNA_i^Metin vitro, while it showed little or reduced interaction with unacylated or lysine-charged tRNA_i^Met. In addition, AIMP3 discriminates Met-tRNA_i^Met from Met-charged elongator tRNA based on filter-binding assay. Pull‐down assay revealed that AIMP3 and MRS had noncompetitive interaction with eukaryotic initiation factor 2 (eIF2) γ subunit (eIF2γ), which is in charge of binding with Met-tRNA_i^Met for the delivery of Met-tRNA_i^Met to ribosome. AIMP3 recruited active eIF2γ to the MRS-AIMP3 complex, and the level of Met-tRNA_i^Met bound to eIF2 complex was reduced by AIMP3 knockdown resulting in reduced protein synthesis. All these results suggested the novel function of AIMP3 as a critical mediator of Met-tRNA_i^Met transfer from MRS to eIF2 complex for the accurate and efficient translation initiation.     

Genetic interactions between a null allele of the RIT1 gene encoding an initiator tRNA-specific modification enzyme and genes encoding translation factors in Saccharomyces cerevisiae

The Saccharomyces cerevisiae gene RIT1 encodes a phospho-ribosyl transferase that exclusively modifies the initiator tRNA (tRNA^Met _i) by the addition of a 2′-O-ribosyl phosphate group to Adenosine 64. As a result, tRNA^Met _i is prevented from participating in the elongation steps of protein synthesis. We previously showed that the modification is not essential for the function of tRNA^Met _i in the initiation of translation, since rit1 null strains are viable and show no obvious growth defects. Here, we demonstrate that yeast strains in which a rit1 null allele is combined with mutations in any of the genes for the three subunits of eukaryotic initiation factor-2 (eIF-2), or with disruption alleles of two of the four initiator methionine tRNA (IMT) genes, show synergistic growth defects. A multicopy plasmid carrying an IMT gene can alleviate these defects. On the other hand, introduction of a high-copy-number plasmid carrying the TEF2 gene, which encodes the eukaryotic elongation factor 1α (eEF-1α), into rit1 null strains with two intact IMT genes had the opposite effect, indicating that increased levels of eEF-1α are deleterious to these strains, presumably due to sequestration of the unmodified met-tRNA^Met _i for elongation. Thus, under conditions in which the components of the ternary met-tRNA^Met _i:GTP:eIF-2 complex become limiting or are functionally impaired, the presence of the 2′-O-ribosyl phosphate modification in tRNA^Met _i is important for the provision of adequate amounts of tRNA^Met _i for formation of this ternary complex.     

Incorporation of methionine from met-tRNA-Met-F into internal positions of polypeptides by mouse liver polysomes

Two methionine accepting tRNA species corresponding to tRNA_F^Met and tRNA_M^Met from mouse ascites tumor cells were tested for their ability to donate methionine into internal positions of growing polypeptide chains on mouse liver polysomes. Both tRNA species can function in the elongation of polypeptide chains as judged by their ability to incorporate methionine into protein in the absence of chain initiation. The insertion of methionine into internal positions of polypeptide chains from Met-tRNA_F^Met was confirmed by Edman degradation and CNBr cleavage. When both tRNA^Met species were present in saturating concentrations in the cell-free system a strong preference for the incorporation of methionine from Met-tRNA_M^Met became apparent.     

Tissue kallikrein processes small proenkephalin peptides

Tissue kallikrein may play a role in processing precursor polypeptide hormones. We investigated whether hydrolysis of natural enkephalin precursors, peptide F and bovine adrenal medulla docosapeptide (BAM-22P), by hog pancreatic kallikrein is consistent with this concept. Incubation of peptide F with this tissue kallikrein resulted in the release of Met⁵-enkephalin and Met⁵-Lys⁶-enkephalin. Met⁵-Lys⁶-enkephalin was the main peptide released, indicating that the major cleavage site was between two lysine residues. At 37°C and pH 8.5, the K_M values for formation of Met⁵-enkephalin and Met⁵-Lys⁶-enkephalin were 129 and 191 μM, respectively. Corresponding k_cat values were 0.001 and 0.03 s⁻¹ and k_cat/K_M ratios were 8 and 1.6·10² M⁻¹ · s⁻¹, respectively. Cleavage of peptide F at acidic pH (5.5) was negligible. When BAM-22P was used as a substrate, Met⁵-Arg⁶-enkephalin was released, thus indicating cleavage between two arginine residues. At pH 8.5, K_M was 64 μM, k_cat was 4.5 s⁻¹, and the k_cat/K_M ratio was 7 · 10⁴ M⁻¹ · s⁻¹. At 5.5, the pH of the secretory granules, K_M, k_cat and k_cat/K_M were 184 μM, 1.9 s⁻¹ and 10⁴ M⁻¹ · s⁻¹, respectively. It is unlikely that peptide F could be a substrate for kallikrein in vivo; however, tissue kallikrein could aid in processing proenkephalin precursors such as BAM-22P by cleaving Arg-Arg peptide bonds.     

A critical role of water in the specific cleavage of the anticodon loop of some eukaryotic methionine initiator tRNAs

We have noticed that during a long storage and handling, the plant methionine initiator tRNA is spontaneously hydrolyzed within the anticodon loop at the C34-A35 phosphodiester bond. A literature search indicated that there is also the case for human initiator tRNA^Met but not for yeast tRNA^Met _i or E. coli tRNA^Met _f. All these tRNAs have an identical nucleotide sequence of the anticodon stems and loops with only one difference at position 33 within the loop. It means that cytosine 33 (C33) makes the anticodon loop of plant and human tRNA^Met _i susceptible to the specific cleavage reaction. Using crystallographic data of tRNA^Met _f of E. coli with U33, we modeled the anticodon loop of this tRNA with C33. We found that C33 within the anticodon loop creates a pocket that can accomodate a hydrogen bonded water molecule that acts as a general base and catalyzes a hydrolysis of C-A bond. We conclude that a single nucleotide change in the primary structure of tRNA^Met _i made changes in hydration pattern and readjustment in hydrogen bonding which lead to a cleavage of the phosphodiester bond.     

Alkyl Hydroperoxide Reductase Repair by Helicobacter pylori Methionine Sulfoxide Reductase

Protein exposure to oxidants such as HOCl leads to formation of methionine sulfoxide (MetSO) residues, which can be repaired by methionine sulfoxide reductase (Msr). A Helicobacter pylori msr strain was more sensitive to HOCl-mediated killing than the parent. Because of its abundance in H. pylori and its high methionine content, alkyl hydroperoxide reductase C (AhpC) was hypothesized to be prone to methionine oxidation. AhpC was expressed as a recombinant protein in Escherichia coli. AhpC activity was abolished by HOCl, while all six methionine residues of the enzyme were fully to partially oxidized. Upon incubation with a Msr repair mixture, AhpC activity was restored to nonoxidized levels and the MetSO residues were repaired to methionine, albeit to different degrees. The two most highly oxidized and then Msr-repaired methionine residues in AhpC, Met₁₀₁ and Met₁₃₃, were replaced with isoleucine residues by site-directed mutagenesis, either individually or together. E. coli cells expressing variant versions were more sensitive to t-butyl hydroperoxide than cells expressing native protein, and purified AhpC variant proteins had 5% to 39% of the native enzyme activity. Variant proteins were still able to oligomerize like the native version, and circular dichroism (CD) spectra of variant proteins revealed no significant change in AhpC conformation, indicating that the loss of activity in these variants was not related to major structural alterations. Our results suggest that both Met₁₀₁ and Met₁₃₃ residues are important for AhpC catalytic activity and that their integrity relies on the presence of a functional Msr.     

Genetic Studies of Sulfadiazine-resistant and Methionine-requiring Neisseria Isolated From Clinical Material

Deoxyribonucleate (DNA) preparations were extracted from Neisseria meningitidis (four isolates from spinal fluid and blood) and N. gonorrhoeae strains, all of which were resistant to sulfadiazine upon primary isolation. These DNA preparations, together with others from in vitro mutants of N. meningitidis and N. perflava, were examined in transformation tests by using as recipient a drug-susceptible strain of N. meningitidis (Ne 15 Sul-s Met⁺) which was able to grow in a methionine-free defined medium. The sulfadiazine resistance typical of each donor was introduced into the uniform constitution of this recipient. Production of p-aminobenzoic acid was not significantly altered thereby. Transformants elicited by DNA from the N. meningitidis clinical isolates were resistant to at least 200 μg of sulfadiazine/ml, and did not show a requirement for methionine (Sul-r Met⁺). DNA from six strains of N. gonorrhoeae, which were isolated during the period of therapeutic use of sulfonamides, conveyed lower degrees of resistance and, invariably, a concurrent methionine requirement (Sul-r/Met⁻). The requirement of these transformants, and that of in vitro mutants selected on sulfadiazine-agar, was satisfied by methionine, but not by vitamin B₁₂, homocysteine, cystathionine, homoserine, or cysteine. Sul-r Met⁺ and Sul-r/Met⁻ loci could coexist in the same genome, but were segregated during transformation. On the other hand, the dual Sul-r/Met⁻ properties were not separated by recombination, but were eliminated together. DNA from various Sul-r/Met⁻ clones tested against recipients having nonidentical Sul-r/Met⁻ mutant sites yielded Sul-s Met⁺ transformants. The met locus involved is genetically complex, and will be a valuable tool for studies of genetic fine structure of members of Neisseria, and of genetic homology between species.     

Identification of a protein at the ribosomal donor-site by affinity labeling

p-nitrophenylcarbamyl-methionyl-tRNA_f^Met is shown to act as an analogue of fMet-tRNA_f^Met in initiation complex formation. It binds to E. coli ribosomes in the presence of initiation factors and R 17-RNA as messenger. Covalent bond formation occurs in the complex between the Met-tRNA_f^Met derivative and protein of the 50 S ribosomal subunit. The protein labeled predominantly in the reaction has been identified as L 27 indicating that this protein is located at the donor-site of the ribosome.     

Selective changes in methionine tRNA species during development of the posterior silkglands of Bombyx mori.

Transfer RNA with methionine acceptor activity isolated from two distinct physiological stages of the developing posterior silkgland of the silkworm, $\text{Bombyx mori}$, was examined. The tRNA from both stages could be fractionated on benzoylated DEAE-cellulose colum into two iso-accepting species, tRNA₁^Met and tRNA₂^Met. The molar quantity per gland of tRNA₁^Met species, which was also formylatable with the $\text{E. coli}$ enzymes, increased twelve-fold as the gland differentiates to produce a large amount of a single protein, silk-fibroin. Since methionine is not a part of silk-fibroin, the preferential increase in tRNA₁^Met content would reflect the increased biological activity and the rapid rate of protein synthesis during the terminal differentiation of posterior silkgland.     

The Levels of a Universally Conserved tRNA Modification Regulate Cell Growth

N⁶-Threonylcarbamoyl-adenosine (t⁶A) is a universal modification occurring at position 37 in nearly all tRNAs that decode A-starting codons, including the eukaryotic initiator tRNA (tRNA_i^Met). Yeast lacking central components of the t⁶A synthesis machinery, such as Tcs3p (Kae1p) or Tcs5p (Bud32p), show slow-growth phenotypes. In the present work, we show that loss of the Drosophila tcs3 homolog also leads to a severe reduction in size and demonstrate, for the first time in a non-microbe, that Tcs3 is required for t⁶A synthesis. In Drosophila and in mammals, tRNA_i^Met is a limiting factor for cell and animal growth. We report that the t⁶A-modified form of tRNA_i^Met is the actual limiting factor. We show that changing the proportion of t⁶A-modified tRNA_i^Met, by expression of an un-modifiable tRNA_i^Met or changing the levels of Tcs3, regulate target of rapamycin (TOR) kinase activity and influences cell and animal growth in vivo. These findings reveal an unprecedented relationship between the translation machinery and TOR, where translation efficiency, limited by the availability of t⁶A-modified tRNA, determines growth potential in eukaryotic cells.     

Purification Of Methionine Acceptor tRNA On Arginine-Agarose

Crude E. coli tRNA or enriched methionine acceptor tRNA can be separated into three stiecies on a column of arginine-agarose. The first peak eluted is tRNA^Met and the latter two peaks are two forms of tRNA^Met _f. From crude tRNA, tRNA^Met _m is obtained in approximately 50% purity. Arginine-agarose separates enriched methionine accepting tRNA into three homogeneous fractions.     

Yeast AEP3p Is an Accessory Factor in Initiation of Mitochondrial Translation

Initiation of protein synthesis in mitochondria and chloroplasts normally uses a formylated initiator methionyl-tRNA (fMet-tRNA_f^Met). However, mitochondrial protein synthesis in Saccharomyces cerevisiae can initiate with nonformylated Met-tRNA_f^Met, as demonstrated in yeast mutants in which the nuclear gene encoding mitochondrial methionyl-tRNA formyltransferase (FMT1) has been deleted. The role of formylation of the initiator tRNA is not known, but in vitro formylation increases binding of Met-tRNA_f^Met to translation initiation factor 2 (IF2). We hypothesize the existence of an accessory factor that assists mitochondrial IF2 (mIF2) in utilizing unformylated Met-tRNA_f^Met. This accessory factor might be unnecessary when formylated Met-tRNA_f^Met is present but becomes essential when only the unformylated species are available. Using a synthetic petite genetic screen in yeast, we identified a mutation in the AEP3 gene that caused a synthetic respiratory-defective phenotype together with Δfmt1. The same aep3 mutation also caused a synthetic respiratory defect in cells lacking formylated Met-tRNA_f^Met due to loss of the MIS1 gene that encodes the mitochondrial C₁-tetrahydrofolate synthase. The AEP3 gene encodes a peripheral mitochondrial inner membrane protein that stabilizes mitochondrially encoded ATP6/8 mRNA. Here we show that the AEP3 protein (Aep3p) physically interacts with yeast mIF2 both in vitro and in vivo and promotes the binding of unformylated initiator tRNA to yeast mIF2. We propose that Aep3p functions as an accessory initiation factor in mitochondrial protein synthesis.     

Genetic interactions between a null allele of the RIT1 gene encoding an initiator tRNA-specific modification enzyme and genes encoding translation factors in Saccharomyces cerevisiae

The Saccharomyces cerevisiae gene RIT1 encodes a phospho-ribosyl transferase that exclusively modifies the initiator tRNA (tRNA^Met _i) by the addition of a 2′-O-ribosyl phosphate group to Adenosine 64. As a result, tRNA^Met _i is prevented from participating in the elongation steps of protein synthesis. We previously showed that the modification is not essential for the function of tRNA^Met _i in the initiation of translation, since rit1 null strains are viable and show no obvious growth defects. Here, we demonstrate that yeast strains in which a rit1 null allele is combined with mutations in any of the genes for the three subunits of eukaryotic initiation factor-2 (eIF-2), or with disruption alleles of two of the four initiator methionine tRNA (IMT) genes, show synergistic growth defects. A multicopy plasmid carrying an IMT gene can alleviate these defects. On the other hand, introduction of a high-copy-number plasmid carrying the TEF2 gene, which encodes the eukaryotic elongation factor 1α (eEF-1α), into rit1 null strains with two intact IMT genes had the opposite effect, indicating that increased levels of eEF-1α are deleterious to these strains, presumably due to sequestration of the unmodified met-tRNA^Met _i for elongation. Thus, under conditions in which the components of the ternary met-tRNA^Met _i:GTP:eIF-2 complex become limiting or are functionally impaired, the presence of the 2′-O-ribosyl phosphate modification in tRNA^Met _i is important for the provision of adequate amounts of tRNA^Met _i for formation of this ternary complex. Received: 20 November 1998 / Accepted: 7 April 1999     

Sequences of initiator and elongator methionine tRNAs in bean mitochondria

Summary Two bean mitochondria methionine transfer RNAs, purified by RPC-5 chromatography and two-dimensional gel electrophoresis, have been sequenced usingin vitro post-labeling techniques.One of these tRNAs^Met has been identified by formylation using anE. coli enzyme as the mitochondrial tRNA_F ^Met. It displays strong structural homologies with prokaryotic and chloroplast tRNA_F ^Met sequences (70.1–83.1%) and with putative initiator tRNA_m ^Met genes described for wheat, maize andOenothera mitochondrial genomes (88.3–89.6%).The other tRNA^Met, which is the mitochondrial elongator tRNA_F ^Met, shows a high degree of sequence homology (93.3–96%& with chloroplast tRNA_m ^Met, but a weak homology (40.7%) with a sequenced maize mitochondrial putative elongator tRNA_m ^Met gene.Bean mitochondrial tRNA_F ^Met and tRNA_m ^Met were hybridized to Southern blots of the mitochondrial genomes of wheat and maize, whose maps have been recently published (15, 22), in order to locate the position of their genes.     

Construction,aminoacylation and 80 S ribosomal complex formation with a yeast initiator tRNA having an arginine CCU anticodon

The digestion of yeast initiator methionine tRNA with mung bean nuclease and U₂ ribonuclease yielded 5'- and 3'-fragments, respectively. These two fragments together represent the entire tRNA sequence except for A₃₅, the central nucleotide of the anticodon, and the CCA terminus. Using RNA ligase, a cytosine was added and the anticodon loop having a C₃₅ was reformed. Subsequent treatment of this product with CCA-transferase yielded a full-length methionine tRNA having an arginine CCU anticodon. This recombinant tRNA^Met (CCU) was charged with methionine by the yeast tRNA synthetase. Aminoacylation of the recombinant was however less extensive than in the case of native tRNA^Met (CAU). After aminoacylation the recombinant tRNA formed an 80 S ribosomal complex.     

Translation of mengovirus RNA in Ehrlich ascites cell extracts

Mengovirus RNA was translated in Ehrlich ascites cell extracts using as radioactive precursors f[³⁵S]Met tRNA_F^Met and [³⁵S]Met tRNA_M^Met to label the products in N-terminal and internal positions, respectively. Tryptic peptides were compared with those derived from purified [³⁵S]Met-labeled mengovirus. The results indicate that the sequences corresponding to the viral coat polypeptides are preceded by a short “lead-in” peptide which is probably removed by a cleavage process in infected cells.