Recognition of tRNAs by Methionyl-tRNA transformylase from mammalian mitochondria

Protein synthesis involves two methionine-isoaccepting tRNAs, an initiator and an elongator. In eubacteria, mitochondria, and chloroplasts, the addition of a formyl group gives its full functional identity to initiator Met-tRNA(Met). In Escherichia coli, it has been shown that the specific action of methionyl-tRNA transformylase on Met-tRNA(f)(Met) mainly involves a set of nucleotides in the acceptor stem, particularly a C(1)A(72) mismatch. In animal mitochondria, only one tRNA(Met) species has yet been described. It is admitted that this species can engage itself either in initiation or elongation of translation, depending on the presence or absence of a formyl group. In the present study, we searched for the identity elements of tRNA(Met) that govern its formylation by bovine mitochondrial transformylase. The main conclusion is that the mitochondrial formylase preferentially recognizes the methionyl moiety of its tRNA substrate. Moreover, the relatively small importance of the tRNA acceptor stem in the recognition process accounts for the protection against formylation of the mitochondrial tRNAs that share with tRNA(Met) an A(1)U(72) motif.     

Nucleotides of tRNA governing the specificity of Escherichia coli methionyl-tRNA(fMet) formyltransferase.

In Escherichia coli, the free amino group of the aminoacyl moiety of methionyl-tRNA(fMet) is specifically modified by a transformylation reaction. To identify the nucleotides governing the recognition of the tRNA substrate by the formylase, initiator tRNA(fMet) was changed into an elongator tRNA with the help of an in vivo selection method. All the mutations isolated were in the tRNA acceptor arm, at positions 72 and 73. The major role of the acceptor arm was further established by the demonstration of the full formylability of a chimaeric tRNA(Met) containing the acceptor stem of tRNA(fMet) and the remaining of the structure of tRNA(mMet). In addition, more than 30 variants of the genes encoding tRNA(mMet) or tRNA(fMet) have been constructed, the corresponding mutant tRNA products purified and the parameters of the formylation reaction measured. tRNA(mMet) became formylatable by the only change of the G1.C72 base-pair into C1-A72. It was possible to render tRNA(mMet) as good a substrate as tRNA(fMet) for the formylase by the introduction of a limited number of additional changes in the acceptor stem. In conclusion, A73, G2.C71, C3.G70 and G4.C69 are positive determinants for the specific processing of methionyl-tRNA(fMet) by the formylase while the occurrence of a G.C or C.G base-pair between positions 1 and 72 acts as a major negative determinant. This pattern appears to account fully for the specificity of the formylase and the lack of formylation of any aminoacylated tRNA, excepting the methionyl-tRNA(fMet).     

Involvement of the size and sequence of the anticodon loop in tRNA recognition by mammalian and E. coli methionyl-tRNA synthetases.

The rates of the cross-aminoacylation reactions of tRNAs(Met) catalyzed by methionyl-tRNA synthetases from various organisms suggest the occurrence of two types of tRNA(Met)/methionyl-tRNA synthetase systems. In this study, the tRNA determinants recognized by mammalian or E. coli methionyl-tRNA synthetases, which are representative members of the two types, have been examined. Like its prokaryotic counterpart, the mammalian enzyme utilizes the anticodon of tRNA as main recognition element. However, the mammalian cytoplasmic elongator tRNA(Met) species is not recognized by the bacterial synthetase, and both the initiator and elongator E. coli tRNA(Met) behave as poor substrates of the mammalian cytoplasmic synthetase. Synthetic genes encoding variants of tRNAs(Met), including the elongator one from mammals, were expressed in E. coli. tRNAs(Met) recognized by a synthetase of a given type can be converted into a substrate of an enzyme of the other type by introducing one-base substitutions in the anticodon loop or stem. In particular, a reduction of the size of the anticodon loop of cytoplasmic mammalian elongator tRNA(Met) from 9 to 7 bases, through the creation of an additional Watson-Crick pair at the bottom of the anticodon stem, makes it a substrate of the prokaryotic enzyme and decreases its ability to be methionylated by the mammalian enzyme. Moreover, enlarging the size of the anticodon loop of E. coli tRNA(Metm) from 7 to 9 bases, by disrupting the base pair at the bottom of the anticodon stem, renders the resulting tRNA a good substrate of the mammalian enzyme, while strongly altering its reaction with the prokaryotic synthetase. Finally, E. coli tRNA(Metf) can be rendered a better substrate of the mammalian enzyme by changing its U33 into a C. This modification makes the sequence of the anticodon loop of tRNA(Metf) identical to that of cytoplasmic initiator tRNA(Met).     

Mitochondrial initiation factor 2 of Trypanosoma brucei binds imported formylated elongator-type tRNA(Met)

The mitochondrion of Trypanosoma brucei lacks tRNA genes. Its translation system therefore depends on the import of nucleus-encoded tRNAs. Thus, except for the cytosol-specific initiator tRNA(Met), all trypanosomal tRNAs function in both the cytosol and the mitochondrion. The only tRNA(Met) present in T. brucei mitochondria is therefore the one which, in the cytosol, is involved in translation elongation. Mitochondrial translation initiation depends on an initiator tRNA(Met) carrying a formylated methionine. This tRNA is then recognized by initiation factor 2, which brings it to the ribosome. To guarantee mitochondrial translation initiation, T. brucei has an unusual methionyl-tRNA formyltransferase that formylates elongator tRNA(Met). In the present study, we have identified initiation factor 2 of T. brucei and shown that its carboxyl-terminal domain specifically binds formylated trypanosomal elongator tRNA(Met). Furthermore, the protein also recognizes the structurally very different Escherichia coli initiator tRNA(Met), suggesting that the main determinant recognized is the formylated methionine. In vivo studies using stable RNA interference cell lines showed that knock-down of initiation factor 2, depending on which construct was used, causes slow growth or even growth arrest. Moreover, concomitantly with ablation of the protein, a loss of oxidative phosphorylation was observed. Finally, although ablation of the methionyl-tRNA formyltransferase on its own did not impair growth, a complete growth arrest was observed when it was combined with the initiation factor 2 RNA interference cell line showing the slow growth phenotype. Thus, these experiments illustrate the importance of mitochondrial translation initiation for growth of procyclic T. brucei.     

Purification of the yeast mitochondrial methionyl-tRNA synthetase. Common and distinctive features of the cytoplasmic and mitochondrial isoenzymes

Yeast-mitochondrial methionyl-tRNA synthetase was purified 1060-fold from mitochondrial matrix proteins of Saccharomyces cerevisiae using a four-step procedure based on affinity chromatography (heparin-Ultrogel, tRNA(Met)-Sepharose, Agarose-hexyl-AMP) to yield to a single polypeptide of high specific activity (1800 U/mg). Like the cytoplasmic methionyl-tRNA synthetase (Mr 85,000), the mitochondrial isoenzyme is a monomer, but of significantly smaller polypeptide size (Mr 65,000). In contrast, the corresponding enzyme of Escherichia coli is a dimer (Mr 152,000) made up of identical subunits. The measured affinity constants of the purified mitochondrial enzyme for methionine and tRNA(Met) are similar to those of the cytoplasmic isoenzyme. However, the two yeast enzymes exhibit clearly different patterns of aminoacylation of heterologous yeast and E. coli tRNA(Met). Furthermore, polyclonal antibodies raised against the two proteins did not show any cross-reactivity by inhibition of enzymatic activity and by the highly sensitive immunoblotting technique, indicating that the two enzymes share little, if any, common antigenic determinants. Taken together, our results further support the belief that the yeast mitochondrial and cytoplasmic methionyl-tRNA synthetases are different proteins coded for by two distinct nuclear genes. Like the yeast cytoplasmic aminoacyl-tRNA synthetases, the mitochondrial enzymes displayed affinity for immobilized heparin. This distinguishes them from the corresponding enzymes of E. coli. Such an unexpected property of the mitochondrial enzymes suggests that they have acquired during evolution a domain for binding to negatively charged cellular components.     

Specific hydrolysis of methionyl-tRNA Met f catalyzed by a purified peptide.

A peptide initiation factor purified from rat liver and promoting the binding of initiator tRNA and model initiators to 40S and 80S ribosome at an acid pH liberates methionine and N-acetylmethionine from Trna Met f at neutral reaction. Phenylalanyl-tRNA, N-acetylphenylalanyl-tRNA and methionyl-tRNA Met m are not hydrolyzed under the same conditions. Hydrolysis of methionyl-tRNA Met f is stimulated by the presence of the 40S ribosomal subunit and preceeds at 37 degrees C until all the substrate has been split. No hydrolysis of initiator tRNA or N-acetylmethionyl-tRNA Met f occurs at 0 degrees C. Hydrolysis is slightly stimulated by GTP and MG2+ but not by KCl. The binding and hydrolyzing activity associated with a single protein factor may have an important function in regulating the rate of peptide initiation.     

A bacterial amber suppressor in Saccharomyces cerevisiae is selectively recognized by a bacterial aminoacyl-tRNA synthetase.

Little is known about the conservation of determinants for the identities of tRNAs between organisms. We showed previously that Escherichia coli tyrosine tRNA synthetase can charge the Saccharomyces cerevisiae mitochondrial tyrosine tRNA in vivo, even though there are substantial sequence differences between the yeast mitochondrial and bacterial tRNAs. The S. cerevisiae cytoplasmic tyrosine tRNA differs in sequence from both its yeast mitochondrial and E. coli counterparts. To test whether the yeast cytoplasmic tyrosyl-tRNA synthetase recognizes the E. coli tRNA, we expressed various amounts of an E. coli tyrosine tRNA amber suppressor in S. cerevisiae. The bacterial tRNA did not suppress any of three yeast amber alleles, suggesting that the yeast enzymes retain high specificity in vivo for their homologous tRNAs. Moreover, the nucleotides in the sequence of the E. coli suppressor that are not shared with the yeast cytoplasmic tyrosine tRNA do not create determinants which are efficiently recognized by other yeast charging enzymes. Therefore, at least some of the determinants that influence in vivo recognition of the tyrosine tRNA are specific to the cell compartment and organism. In contrast, expression of the cognate bacterial tyrosyl-tRNA synthetase together with the bacterial suppressor tRNA led to suppression of all three amber alleles. The bacterial enzyme recognized its substrate in vivo, even when the amount of bacterial tRNA was less than about 0.05% of that of the total cytoplasmic tRNA.     

Structure of crystalline Escherichia coli methionyl-tRNA(f)Met formyltransferase: comparison with glycinamide ribonucleotide formyltransferase.

Formylation of the methionyl moiety esterified to the 3' end of tRNA(f)Met is a key step in the targeting of initiator tRNA towards the translation start machinery in prokaryotes. Accordingly, the presence of methionyl-tRNA(f)Met formyltransferase (FMT), the enzyme responsible for this formylation, is necessary for the normal growth of Escherichia coli. The present work describes the structure of crystalline E.coli FMT at 2.0 A, resolution. The protein has an N-terminal domain containing a Rossmann fold. This domain closely resembles that of the glycinamide ribonucleotide formyltransferase (GARF), an enzyme which, like FMT, uses N-10 formyltetrahydrofolate as formyl donor. However, FMT can be distinguished from GARF by a flexible loop inserted within its Rossmann fold. In addition, FMT possesses a C-terminal domain with a beta-barrel reminiscent of an OB fold. This latter domain provides a positively charged side oriented towards the active site. Biochemical evidence is presented for the involvement of these two idiosyncratic regions (the flexible loop in the N-terminal domain, and the C-terminal domain) in the binding of the tRNA substrate.     

Yeast mitochondrial methionine initiator tRNA: characterization and nucleotide sequence.

Two methionine tRNAs from yeast mitochondria have been purified. The mitochondrial initiator tRNA has been identified by formylation using a mitochondrial enzyme extract. E. coli transformylase however, does not formylate the yeast mitochondrial initiator tRNA. The sequence was determined using both 32P-in vivo labeled and 32P-end labeled mt tRNAf(Met). This tRNA, unlike N. crassa mitochondrial tRNAf(Met), has two structural features typical of procaryotic initiator tRNAs: (i) it lacks a Watson-Crick base-pair at the end of the acceptor stem and (ii) has a T-psi-C-A sequence in loop IV. However, both yeast and N. crassa mitochondrial initiator tRNAs have a U11:A24 base-pair in the D-stem unlike procaryotic initiator tRNAs which have A11:U24. Interestingly, both mitochondrial initiator tRNAs, as well as bean chloroplast tRNAf(Met), have only two G:C pairs next to the anticodon loop, unlike any other initiator tRNA whatever its origin. In terms of overall sequence homology, yeast mitochondrial tRNA(Met)f differs from both procaryotic or eucaryotic initiator tRNAs, showing the highest homology with N. crassa mitochondrial initiator tRNA.     

Purification and characterization of yeast mitochondrial initiation factor 2

Yeast mitochondrial initiation factor 2 (ymIF2) is encoded by the nuclear IFM1 gene. A His-tagged version of ymIF2, lacking its predicted mitochondrial presequence, was expressed in Escherichia coli and purified. Purified ymIF2 bound both E. coli fMet-tRNA(f)(Met) and Met-tRNA(f)(Met), but binding of formylated initiator tRNA was about four times higher than that of the unformylated species under the same conditions. In addition, the isolated ymIF2 was compared to E. coli IF2 in four other assays commonly used to characterize this initiation factor. Formylated and nonformylated Met-tRNA(f)(Met) were bound to E. coli 30S ribosomal subunits in the presence of ymIF2, GTP, and a short synthetic mRNA. The GTPase activity of ymIF2 was found to be dependent on the presence of E. coli ribosomes. The ymIF2 protected fMet-tRNA(f)(Met) to about the same extent as E. coli IF2 against nonenzymatic deaminoacylation. In contrast to E. coli IF2, the complex formed between ymIF2 and fMet-tRNA(f)(Met) was not stable enough to be analyzed in a gel shift assay. In similarity to other IF2 species isolated from bacteria or bovine mitochondria, the N-terminal domain could be eliminated without loss of initiator tRNA binding activity.     

Purification and some properties of a protein binding and deacylating initiator transfer ribonucleic acid

1. A protein factor promoting the binding of initiator tRNA to the 40S ribosomal subunit was purified to homogeneity (more than 2500-fold) from rat liver cytosol. It has a mol.wt. of 265000 and is composed of four subunits of identical molecular weight. 2. This factor directs the binding of methionyl-tRNA(fMet) and to a lesser extent also of N-acetylphenylalanyl-tRNA, but not of methionyl-tRNA(Met) or phenylalanyl-tRNA, to the smaller ribosomal subunit at high concentrations of GTP (8-10mm) with an optimum at pH4.0. As evidenced by sucrose-density-gradient centrifugation, initiator tRNA becomes bound to the 40S subunit or to 80S ribosomes. 3. A deacylase activity specific for methionyl-tRNA(fMet) is associated with the pure factor. The factor significantly stimulates the translation of natural message in systems containing polyribosomes and both purified peptide-elongation factors. 4. The factor binds initiator tRNA or GTP to form unstable binary complexes and forms a ternary complex with methionyl-tRNA(fMet) and GTP. This complex is relatively stable. 5. In the absence of any cofactors the factor forms a stable complex with 40S and 80S ribosomes. This preformed ribosomal complex binds efficiently initiator tRNA at pH7.5 and low concentrations of GTP (1-2mm). The ternary complex of the factor with methionyl-tRNA(fMet) and GTP may be liberated from this ribosomal complex. 6. A protein factor capable of promoting the binding and simultaneously the deacylation of initiator tRNA may apparently have a regulatory function in physiological gene translation by removing an excess of methionyl-tRNA(fMet) not required for translation.     

Characterization of a chemically synthesized RNA having the sequence of the yeast initiator tRNA(Met)

A 75-unit long oligoribonucleotide corresponding to the sequence of the Saccharomyces cerevisiae initiator tRNA was synthesized chemically. The crude RNA was purified, and the sequence was verified by RNA sequencing techniques. A particularly useful purification step involved hydrophobic chromatography on BND-cellulose. The purified RNA could be aminoacylated to 28% of a bona fide initiator tRNA(Met) sample and threonylated to 76% of the level observed with native tRNA(fMet) from E. coli.     

Mutations in MTFMT underlie a human disorder of formylation causing impaired mitochondrial translation

The metazoan mitochondrial translation machinery is unusual in having a single tRNA(Met) that fulfills the dual role of the initiator and elongator tRNA(Met). A portion of the Met-tRNA(Met) pool is formylated by mitochondrial methionyl-tRNA formyltransferase (MTFMT) to generate N-formylmethionine-tRNA(Met) (fMet-tRNA(met)), which is used for translation initiation; however, the requirement of formylation for initiation in human mitochondria is still under debate. Using targeted sequencing of the mtDNA and nuclear exons encoding the mitochondrial proteome (MitoExome), we identified compound heterozygous mutations in MTFMT in two unrelated children presenting with Leigh syndrome and combined OXPHOS deficiency. Patient fibroblasts exhibit severe defects in mitochondrial translation that can be rescued by exogenous expression of MTFMT. Furthermore, patient fibroblasts have dramatically reduced fMet-tRNA(Met) levels and an abnormal formylation profile of mitochondrially translated COX1. Our findings demonstrate that MTFMT is critical for efficient human mitochondrial translation and reveal a human disorder of Met-tRNA(Met) formylation.     

Metal ion and substrate structure dependence of the processing of tRNA precursors by RNase P and M1 RNA

A synthetic tRNA precursor analog containing the structural elements of Escherichia coli tRNA(Phe) was characterized as a substrate for E. coli ribonuclease P and for M1 RNA, the catalytic RNA subunit. Processing of the synthetic precursor exhibited a Mg2+ dependence quite similar to that of natural tRNA precursors such as E. coli tRNA(Tyr) precursor. It was found that Sr2+, Ca2+, and Ba2+ ions promoted processing of the dimeric precursor at Mg2+ concentrations otherwise insufficient to support processing; very similar behavior was noted for E. coli tRNA(Tyr). As noted previously for natural tRNA precursors, the absence of the 3'-terminal CA sequence in the synthetic precursor diminished the facility of processing of this substrate by RNase P and M1 RNA. A study of the Mg2+ dependence of processing of the synthetic tRNA dimeric substrate radiolabeled between C75 and A76 provided unequivocal evidence for an alteration in the actual site of processing by E. coli RNase P as a function of Mg2+ concentration. This property was subsequently demonstrated to obtain (Carter, B. J., Vold, B.S., and Hecht, S. M. (1990) J. Biol. Chem. 265, 7100-7103) for a mutant Bacillus subtilis tRNAHis precursor containing a potential A-C base pair at the end of the acceptor stem.     

Suppressor mutations in Escherichia coli methionyl-tRNA formyltransferase that compensate for the formylation defect of a mutant tRNA aminoacylated with lysine

The specific formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF) is important for the initiation of protein synthesis in eubacteria such as Escherichia coli. In addition to the determinants for formylation present in the initiator tRNA, the nature of the amino acid attached to the tRNA is also important for formylation. We showed previously that a mutant tRNA aminoacylated with lysine was an extremely poor substrate for formylation. As a consequence, it was essentially inactive in initiation of protein synthesis in E. coli. In contrast, the same tRNA, when aminoacylated with methionine, was a good substrate for formylation and was, consequently, quite active in initiation. Here, we report on the isolation of suppressor mutations in MTF which compensate for the formylation defect of the mutant tRNA aminoacylated with lysine. The suppressor mutant has glycine 178 changed to glutamic acid. Mutants with glycine 178 of MTF changed to aspartic acid, lysine, and leucine were generated and were found to be progressively weaker suppressors. Studies on allele specificity of suppression using different mutant tRNAs as substrates suggest that the Gly178 to Glu mutation compensates for the nature of the amino acid attached to the tRNA. We discuss these results in the framework of the crystal structure of the MTF.fMet-tRNA complex published recently.     

Initiation of in vivo protein synthesis with non-methionine amino acids

Methionine is the universal amino acid for initiation of protein synthesis in all known organisms. The amino acid is coupled to a specific initiator methionine tRNA by methionyl-tRNA synthetase. In Escherichia coli, attachment of methionine to the initiator tRNA (tRNA(fMet)) has been shown to be dependent on synthetase recognition of the methionine anticodon CAU (complementary to the initiation codon AUG), [Schulman, L. H., & Pelka, H. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 6755-6759]. We show here that alteration of the anticodon of tRNA(fMet) to GAC or GAA leads to aminoacylation of the initiator tRNA with valine or phenylalanine. In addition, tRNA(fMet) carrying these amino acids initiates in vivo protein synthesis when provided with initiation codons complementary to the modified anticodons. These results indicate that the sequence of the anticodon of tRNA(fMet) dictates the identity of the amino acid attached to the initiator tRNA in vivo and that there are no subsequent steps which prevent initiation of E. coli protein synthesis by valine and phenylalanine. The methods described here also provide a convenient in vivo assay for further examination of the role of the anticodon in tRNA amino acid acceptor identity.     

Initiation of protein synthesis by folate-sufficient and folate-deficient Streptococcus faecalis R: partial purification and properties of methionyl-transfer ribonucleic acid synthetase and methionyl-transfer ribonucleic acid formyltransferase

The initiation of protein synthesis by Streptococcus faecalis R grown in folate-free culture occurs without N-formylation or N-acylation of methionyl-tRNA(f) (Met). Methionyl-tRNA synthetase and methionyl-tRNA formyltransferase were partially purified from S. faecalis grown under normal culture conditions in the presence of folate (plus-folate); the general properties of the enzymes were determined and compared with the properties of the enzymes purified from wild-type cells grown in the absence of folate (minus-folate). S. faecalis methionyl-tRNA synthetase displays optimal activity at pH values between 7.2 and 7.8, requires Mg(2+), and has an apparent molecular weight of 106,000, as determined by gel filtration, and 127,000, as determined by sucrose density gradient centrifugation. The K(m) values of plus-folate methionyl-tRNA synthetase for each of the three substrates in the aminoacylation reaction (l-methionine, adenosine triphosphate, and tRNA) are nearly identical to the respective substrate Michaelis constants of minus-folate methionyl-tRNA synthetase. Furthermore, both plus- and minus-folate S. faecalis methionyl-tRNA synthetases catalyze, at equal rates, the aminoacylation of tRNA(f) (Met) and tRNA(m) (Met) isolated from either plus-folate or minus-folate cells. S. faecalis methionyl-tRNA formyltransferase displays optimal activity at pH values near 7.0, is stimulated by Mg(2+), and has an apparent molecular weight of approximately 29,900 when estimated by sucrose density gradient centrifugation. The K(m) value of plus-folate formyltransferase for plus-folate Met-tRNA(f) (Met) does not differ significantly from that of minus-folate formyltransferase for minus-folate Met-tRNA(f) (Met). Both enzymes can utilize either 10-formyltetrahydrofolate or 10-formyltetrahydropteroyltriglutamate as the formyl donor; the Michaelis constant for the monoglutamyl pteroyl coenzyme is slightly less than that of the triglutamyl pteroyl coenzyme for both transformylases. Tetrahydrofolate and uncharged tRNA(f) (Met) are competitive inhibitors of both plus- and minus-folate S. faecalis formyltransferase; folic acid, pteroic acid, aminopterin, and Met-tRNA(m) (Met) are not inhibitory. These results indicate that the presence or absence of folic acid in the culture medium of S. faecalis has no apparent effect on either methionyl-tRNA synthetase or methionyl-tRNA formyltransferase, the two enzymes directly involved in the formation of formylmethionyl-tRNA(f) (Met). Therefóre, the lack of N-formylation of Met-tRNA(f) (Met) in minus-folate S. faecalis is due to the absence of the formyl donor, a 10-formyl-tetrahydropteroyl derivative. Although the general properties of S. faecalis methionyl-tRNA synthetase are similar to those of other aminoacyl-tRNA synthetases, S. faecalis methionyl-tRNA formyltransferase differs from other previously described transformylases in certain kinetic parameters.     

A single base pair dominates over the novel identity of an Escherichia coli tyrosine tRNA in Saccharomyces cerevisiae.

The Escherichia coli su+3 tyrosine tRNA was shown recently to be a leucine-specific tRNA in Saccharomyces cerevisiae. This finding raises the possibility that some determinants for tRNA identity in E. coli may be different in S. cerevisiae. To investigate whether the fungal system is sensitive to the major determinant for alanine acceptance in E. coli, a single G3 . U70 base pair was introduced into the acceptor helix of the su+3 tyrosine tRNA. This substitution converts the identity of the E. coli suppressor in S. cerevisiae from leucine to alanine. Thus, as in E. coli, G3 . U70 is a strong determinant for alanine acceptance that can dominate over other features in a tRNA that might be recognized by alternative charging enzymes.