Mycobacterium tuberculosis Rv2118c codes for a single-component homotetrameric m1A58 tRNA methyltransferase

Modified nucleosides in tRNAs play important roles in tRNA structure, biosynthesis and function, and serve as crucial determinants of bacterial growth and virulence. In the yeast Saccharomyces cerevisiae, mutants defective in N1-methylation of a highly conserved adenosine (A58) in the TPsiC loop of initiator tRNA are non-viable. The yeast m1A58 methyltransferase is a heterotetramer consisting of two different polypeptide chains, Gcd14p and Gcd10p. Interestingly, while m1A58 is not found in most eubacteria, the mycobacterial tRNAs have m1A58. Here, we report on the cloning, overexpression, purification and biochemical characterization of the Rv2118c gene-encoded protein (Rv2118p) from Mycobacterium tuberculosis, which is homologous to yeast Gcd14p. We show that Rv2118c codes for a protein of approximately 31 kDa. Activity assays, modified base analysis and primer extension experiments using reverse transcriptase reveal that Rv2118p is an S-adenosyl-l-methionine-dependent methyltransferase which carries out m1A58 modification in tRNAs, both in vivo and in vitro. Remarkably, when expressed in Escherichia coli, the enzyme methylates the endogenous E.coli initiator tRNA essentially quantitatively. Furthermore, unlike its eukaryotic counterpart, which is a heterotetramer, the mycobacterial enzyme is a homotetramer. Also, the presence of rT modification at position 54, which was found to inhibit the Tetrahymena pyriformis enzyme, does not affect the activity of Rv2118p. Thus, the mycobacterial m1A58 tRNA methyltransferase possesses distinct biochemical properties. We discuss aspects of the biological relevance of Rv2118p in M.tuberculosis, and its potential use as a drug target to control the growth of mycobacteria.

Import of amber and ochre suppressor tRNAs into mammalian cells: a general approach to site-specific insertion of amino acid analogues into proteins

A general approach to site-specific insertion of amino acid analogues into proteins in vivo would be the import into cells of a suppressor tRNA aminoacylated with the analogue of choice. The analogue would be inserted at any site in the protein specified by a stop codon in the mRNA. The only requirement is that the suppressor tRNA must not be a substrate for any of the cellular aminoacyl-tRNA synthetases. Here, we describe conditions for the import of amber and ochre suppressor tRNAs derived from Escherichia coli initiator tRNA into mammalian COS1 cells, and we present evidence for their activity in the specific suppression of amber (UAG) and ochre (UAA) codons, respectively. We show that an aminoacylated amber suppressor tRNA (supF) derived from the E. coli tyrosine tRNA can be imported into COS1 cells and acts as a suppressor of amber codons, whereas the same suppressor tRNA imported without prior aminoacylation does not, suggesting that the supF tRNA is not a substrate for any mammalian aminoacyl-tRNA synthetase. These results open the possibility of using the supF tRNA aminoacylated with an amino acid analogue as a general approach for the site-specific insertion of amino acid analogues into proteins in mammalian cells. We discuss the possibility further of importing a mixture of amber and ochre suppressor tRNAs for the insertion of two different amino acid analogues into a protein and the potential use of suppressor tRNA import for treatment of some of the human genetic diseases caused by nonsense mutations.

Twenty-first aminoacyl-tRNA synthetase-suppressor tRNA pairs for possible use in site-specific incorporation of amino acid analogues into proteins in eukaryotes and in eubacteria

Two critical requirements for developing methods for the site-specific incorporation of amino acid analogues into proteins in vivo are (i) a suppressor tRNA that is not aminoacylated by any of the endogenous aminoacyl-tRNA synthetases (aaRSs) and (ii) an aminoacyl-tRNA synthetase that aminoacylates the suppressor tRNA but no other tRNA in the cell. Here we describe two such aaRS-suppressor tRNA pairs, one for use in the yeast Saccharomyces cerevisiae and another for use in Escherichia coli. The "21st synthetase-tRNA pairs" include E. coli glutaminyl-tRNA synthetase (GlnRS) along with an amber suppressor derived from human initiator tRNA, for use in yeast, and mutants of the yeast tyrosyl-tRNA synthetase (TyrRS) along with an amber suppressor derived from E. coli initiator tRNA, for use in E. coli. The suppressor tRNAs are aminoacylated in vivo only in the presence of the heterologous aaRSs, and the aminoacylated tRNAs function efficiently in suppression of amber codons. Plasmids carrying the E. coli GlnRS gene can be stably maintained in yeast. However, plasmids carrying the yeast TyrRS gene could not be stably maintained in E. coli. This lack of stability is most likely due to the fact that the wild-type yeast TyrRS misaminoacylates the E. coli proline tRNA. By using error-prone PCR, we have isolated and characterized three mutants of yeast TyrRS, which can be stably expressed in E. coli. These mutants still aminoacylate the suppressor tRNA essentially quantitatively in vivo but show increased discrimination in vitro for the suppressor tRNA over the E. coli proline tRNA by factors of 2.2- to 6.8-fold.

Importance of the anticodon sequence in the aminoacylation of tRNAs by methionyl-tRNA synthetase and by valyl-tRNA synthetase in an Archaebacterium

The mode of recognition of tRNAs by aminoacyl-tRNA synthetases and translation factors is largely unknown in archaebacteria. To study this process, we have cloned the wild type initiator tRNA gene from the moderate halophilic archaebacterium Haloferax volcanii and mutants derived from it into a plasmid capable of expressing the tRNA in these cells. Analysis of tRNAs in vivo show that the initiator tRNA is aminoacylated but is not formylated in H. volcanii. This result provides direct support for the notion that protein synthesis in archaebacteria is initiated with methionine and not with formylmethionine. We have analyzed the effect of two different mutations (CAU-->CUA and CAU-->GAC) in the anticodon sequence of the initiator tRNA on its recognition by the aminoacyl-tRNA synthetases in vivo. The CAU-->CUA mutant was not aminoacylated to any significant extent in vivo, suggesting the importance of the anticodon in aminoacylation of tRNA by methionyl-tRNA synthetase. This mutant initiator tRNA can, however, be aminoacylated in vitro by the Escherichia coli glutaminyl-tRNA synthetase, suggesting that the lack of aminoacylation is due to the absence in H. volcanii of a synthetase, which recognizes the mutant tRNA. Archaebacteria lack glutaminyl-tRNA synthetase and utilize a two-step pathway involving glutamyl-tRNA synthetase and glutamine amidotransferase to generate glutaminyl-tRNA. The lack of aminoacylation of the mutant tRNA indicates that this mutant tRNA is not a substrate for the H. volcanii glutamyl-tRNA synthetase. The CAU-->GAC anticodon mutant is most likely aminoacylated with valine in vivo. Thus, the anticodon plays an important role in the recognition of tRNA by at least two of the halobacterial aminoacyl-tRNA synthetases.

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 protein synthesis in Saccharomyces cerevisiae mitochondria without formylation of the initiator tRNA

Protein synthesis in eukaryotic organelles such as mitochondria and chloroplasts is widely believed to require a formylated initiator methionyl tRNA (fMet-tRNA(fMet)) for initiation. Here we show that initiation of protein synthesis in yeast mitochondria can occur without formylation of the initiator methionyl-tRNA (Met-tRNA(fMet)). The formylation reaction is catalyzed by methionyl-tRNA formyltransferase (MTF) located in mitochondria and uses N(10)-formyltetrahydrofolate (10-formyl-THF) as the formyl donor. We have studied yeast mutants carrying chromosomal disruptions of the genes encoding the mitochondrial C(1)-tetrahydrofolate (C(1)-THF) synthase (MIS1), necessary for synthesis of 10-formyl-THF, and the methionyl-tRNA formyltransferase (open reading frame YBL013W; designated FMT1). A direct analysis of mitochondrial tRNAs using gel electrophoresis systems that can separate fMet-tRNA(fMet), Met-tRNA(fMet), and tRNA(fMet) shows that there is no formylation in vivo of the mitochondrial initiator Met-tRNA in these strains. In contrast, the initiator Met-tRNA is formylated in the respective "wild-type" parental strains. In spite of the absence of fMet-tRNA(fMet), the mutant strains exhibited normal mitochondrial protein synthesis and function, as evidenced by normal growth on nonfermentable carbon sources in rich media and normal frequencies of generation of petite colonies. The only growth phenotype observed was a longer lag time during growth on nonfermentable carbon sources in minimal media for the mis1 deletion strain but not for the fmt1 deletion strain.

Escherichia coli methionyl-tRNA formyltransferase: role of amino acids conserved in the linker region and in the C-terminal domain on the specific recognition of the initiator tRNA

The formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF) is important for the initiation of protein synthesis in eubacteria. We are studying the molecular mechanisms of recognition of the initiator tRNA by Escherichia coli MTF. MTF from eubacteria contains an approximately 100-amino acid C-terminal extension that is not found in the E. coli glycinamide ribonucleotide formyltransferase, which, like MTF, use N(10)-formyltetrahydrofolate as a formyl group donor. This C-terminal extension, which forms a distinct structural domain, is attached to the N-terminal domain through a linker region. Here, we describe the effect of (i) substitution mutations on some nineteen basic, aromatic and other conserved amino acids in the linker region and in the C-terminal domain of MTF and (ii) deletion mutations from the C-terminus on enzyme activity. We show that the positive charge on two of the lysine residues in the linker region leading to the C-terminal domain are important for enzyme activity. Mutation of some of the basic amino acids in the C-terminal domain to alanine has mostly small effects on the kinetic parameters, whereas mutation to glutamic acid has large effects. However, the deletion of 18, 20, or 80 amino acids from the C-terminus has very large effects on enzyme activity. Overall, our results support the notion that the basic amino acid residues in the C-terminal domain provide a positively charged channel that is used for the nonspecific binding of tRNA, whereas some of the amino acids in the linker region play an important role in activity of MTF.

Induced fit of a peptide loop of methionyl-tRNA formyltransferase triggered by the initiator tRNA substrate

A 16-aa insertion loop present in eubacterial methionyl-tRNA formyltransferases (MTF) is critical for specific recognition of the initiator tRNA in Escherichia coli. We have studied the interactions between this region of the E. coli enzyme and initiator methionyl-tRNA (Met-tRNA) by using two complementary protection experiments: protection of MTF against proteolytic cleavage by tRNA and protection of tRNA against nucleolytic cleavage by MTF. The insertion loop in MTF is uniquely sensitive to cleavage by trypsin. We show that the substrate initiator Met-tRNA protects MTF against trypsin cleavage, whereas a formylation-defective mutant initiator Met-tRNA, which binds to MTF with approximately the same affinity, does not. Also, mutants of MTF within the insertion loop (which are defective in formylation) are not protected by the initiator Met-tRNA. Thus, a functional enzyme-substrate complex is necessary for protection of MTF against trypsin cleavage. Along with other data, these results strongly suggest that a segment of the insertion loop, which is exposed and unstructured in MTF, undergoes an induced fit in the functional MTF.Met-tRNA complex but not in the nonfunctional one. Footprinting experiments show that MTF specifically protects the acceptor stem and the 3'-end region of the initiator Met-tRNA against cleavage by double and single strand-specific nucleases. This protection also depends on formation of a functional MTF.Met-tRNA complex. Thus, the insertion loop interacts mostly with the acceptor stem of the initiator Met-tRNA, which contains the critical determinants for formylation.

Functional interaction of an arginine conserved in the sixteen amino acid insertion module of Escherichia coli methionyl-tRNA formyltransferase with determinants for formylation in the initiator tRNA

Formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF) is important for initiation of protein synthesis in eubacteria. The determinants for formylation are clustered mostly in the acceptor stem of the initiator tRNA. Previous studies suggested that a 16 amino acid insertion loop, present in all eubacterial MTF's (residues 34-49 in the E. coli enzyme), plays an important role in specific recognition of the initiator tRNA. Here, we have analyzed the effect of site-specific mutations of amino acids within this region. We show that an invariant arginine at position 42 within the loop plays a very important role both in the steps of substrate binding and in catalysis. The kinetic parameters of the R42K and R42L mutant enzymes using acceptor stem mutant initiator tRNAs as substrates suggest that arginine 42 makes functional contacts with the determinants at the 3:70 and possibly also the 2:71 base pairs in the acceptor stem of the initiator tRNA. The kinetic parameters of the G41R/R42L double mutant enzyme are essentially the same as those of R42L mutant, suggesting that the requirement for arginine at position 42 cannot be fulfilled by an arginine at position 41. Along with other data, this result suggests that the insertion loop, which is normally unstructured and flexible, adopts a defined conformation upon binding to the tRNA.

Initiation of protein synthesis in mammalian cells with codons other than AUG and amino acids other than methionine

Protein synthesis is initiated universally with the amino acid methionine. In Escherichia coli, studies with anticodon sequence mutants of the initiator methionine tRNA have shown that protein synthesis can be initiated with several other amino acids. In eukaryotic systems, however, a yeast initiator tRNA aminoacylated with isoleucine was found to be inactive in initiation in mammalian cell extracts. This finding raised the question of whether methionine is the only amino acid capable of initiation of protein synthesis in eukaryotes. In this work, we studied the activities, in initiation, of four different anticodon sequence mutants of human initiator tRNA in mammalian COS1 cells, using reporter genes carrying mutations in the initiation codon that are complementary to the tRNA anticodons. The mutant tRNAs used are aminoacylated with glutamine, methionine, and valine. Our results show that in the presence of the corresponding mutant initiator tRNAs, AGG and GUC can initiate protein synthesis in COS1 cells with methionine and valine, respectively. CAG initiates protein synthesis with glutamine but extremely poorly, whereas UAG could not be used to initiate protein synthesis with glutamine. We discuss the potential applications of the mutant initiator tRNA-dependent initiation of protein synthesis with codons other than AUG for studying the many interesting aspects of protein synthesis initiation in mammalian cells.

Tetracycline-regulated suppression of amber codons in mammalian cells

As an approach to inducible suppression of nonsense mutations in mammalian cells, we described recently an amber suppression system in mammalian cells dependent on coexpression of Escherichia coli glutaminyl-tRNA synthetase (GlnRS) along with the E. coli glutamine-inserting amber suppressor tRNA. Here, we report on tetracycline-regulated expression of the E. coli GlnRS gene and, thereby, tetracycline-regulated suppression of amber codons in mammalian HeLa and COS-1 cells. The E. coli GlnRS coding sequence attached to a minimal mammalian cell promoter was placed downstream of seven tandem tetracycline operator sequences. Cotransfection of HeLa cell lines expressing a tetracycline transactivator protein, carrying a tetracycline repressor domain linked to part of a herpesvirus VP16 activation domain, with the E. coli GlnRS gene and the E. coli glutamine-inserting amber suppressor tRNA gene resulted in suppression of the amber codon in a reporter chloramphenicol acetyltransferase gene. The tetracycline transactivator-mediated expression of E. coli GlnRS was essentially completely blocked in HeLa or COS-1 cells grown in the presence of tetracycline. Concomitantly, both aminoacylation of the suppressor tRNA and suppression of the amber codon were reduced significantly in the presence of tetracycline.

Suppressor mutations in Escherichia coli methionyl-tRNA formyltransferase: role of a 16-amino acid insertion module in initiator tRNA recognition

The specific formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF; EC 2.1.2.9) is important for the initiation of protein synthesis in eubacteria and in eukaryotic organelles. The determinants for formylation in the tRNA are clustered mostly in the acceptor stem. As part of studies on the molecular mechanism of recognition of the initiator tRNA by MTF, we report here on the isolation and characterization of suppressor mutations in Escherichia coli MTF, which compensate for the formylation defect of a mutant initiator tRNA, lacking a critical determinant in the acceptor stem. We show that the suppressor mutant in MTF has a glycine-41 to arginine change within a 16-amino acid insertion found in MTF from many sources. A mutant with glycine-41 changed to lysine also acts as a suppressor, whereas mutants with changes to aspartic acid, glutamine, and leucine do not. The kinetic parameters of the purified wild-type and mutant Arg-41 and Lys-41 enzymes, determined by using the wild-type and mutant tRNAs as substrates, show that the Arg-41 and Lys-41 mutant enzymes compensate specifically for the strong negative effect of the acceptor stem mutation on formylation. These and other considerations suggest that the 16-amino acid insertion in MTF plays an important role in the specific recognition of the determinants for formylation in the acceptor stem of the initiator tRNA.

Structural studies on tRNA acceptor stem microhelices: exchange of the discriminator base A73 for G in human tRNALeu switches the acceptor specificity from leucine to serine possibly by decreasing the stability of the terminal G1-C72 base pair

Correct recognition of transfer RNAs (tRNAs) by aminoacyl-tRNA synthetases (aaRS) is crucial to the maintenance of translational fidelity. The discriminator base A73 in human tRNALeuis critical for its specific recognition by the aaRS. Exchanging A73 for G abolishes leucine acceptance and converts it into a serine acceptor in vitro . Two RNA microhelices of 24 nt length that correspond to the tRNALeuacceptor stem and differ only in the discriminator base were synthesized: a wild-type tRNALeumicrohelix, where nt 21 corresponds to the discriminator base position 73, and an A21G mutant microhelix. To investigate whether different identities of both tRNAs are caused by conformational differences, NMR and UV melting experiments were performed on both microhelices. Two-dimentional NOESY spectra showed both microhelices to exhibit the same overall conformation at their 3'-CCA ends. Thermodynamic analysis and melting behaviour of the base-paired imino protons observed by NMR spectroscopy suggest that the A21G (A73G in tRNA) exchange results in a decrease of melting transition cooperativity and a destabilization of the terminal G1-C20 (G1-C72 in tRNA) base pair. Furthermore, the fact that this 3'-terminal imino proton is more solvent-exposed at physiological temperature might be another indication for the importance of the stability of the terminal base pair for specific tRNA recognition.

Lysine 207 as the site of cross-linking between the 3'-end of Escherichia coli initiator tRNA and methionyl-tRNA formyltransferase

The specific formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF) is important for initiation of protein synthesis in Escherichia coli. In attempts to identify regions of MTF that come close to the 3'-end of the tRNA, we oxidized 32P-3'-end-labeled E. coli initiator methionine tRNA with sodium metaperiodate and cross-linked it to MTF. The cross-linked MTF was separated from uncross-linked MTF by DEAE-cellulose chromatography, and the tRNA in the cross-linked MTF was hydrolyzed with nuclease P1 and RNase T1, leaving behind an oxidized fragment of [32P]AMP attached to MTF. Trypsin digestion of the cross-linked MTF followed by high pressure liquid chromatography of the digest yielded two peaks of radioactive peptides, I* and II*. These peptides were characterized by N- and/or C-terminal sequencing and by matrix-assisted laser desorption ionization mass spectroscopy. Peptide I* contained amino acids Gln186-Lys210 with Lys207 as the site of the cross-link. Peptide II*, a partial digestion product, contained amino acids Gln186-Arg214 also with Lys207 as the site of the cross-link. The molecular masses of peptides I* and II* indicate that the final product of the cross-linking reaction between the periodate-oxidized AMP moiety of the tRNA and Lys207 is most likely a morpholino derivative rather than a reduced Schiff's base.

Effect of the amino acid attached to Escherichia coli initiator tRNA on its affinity for the initiation factor IF2 and on the IF2 dependence of its binding to the ribosome

We show that the nature of the amino acid in the formylaminoacyl-tRNA influences initiation factor (IF) 2 dependence of its ribosome binding and that this IF2 dependence reflects the relative affinity of the formylaminoacyl-tRNA for the initiation factor IF2. We compared the template-dependent ribosome binding activities, in the presence of initiation factors, of wild type and anticodon sequence mutants of Escherichia coli initiator tRNAs that carry formylmethionine (fMet), formylglutamine (fGln), or formylvaline (fVal). The fGln-tRNA bound less well than fMet-tRNA whereas the fVal-tRNA bound as well as fMet-tRNA. The rate and extent of binding of fGln-tRNA to the ribosome was significantly increased by further addition of purified initiation factor IF2. In contrast, the binding of fVal-tRNA or fMet-tRNA was not affected much by the addition of IF2. Using gel mobility shift assay, we have measured the apparent Kd values of the IF2.formylaminoacyl-tRNA binary complexes. These are 1.8, 3.5, and 10.5 microM for fMet-tRNA, fVal-tRNA, and fGln-tRNA, respectively.

Ribosome-initiator tRNA complex as an intermediate in translation initiation in Escherichia coli revealed by use of mutant initiator tRNAs and specialized ribosomes

For functional studies of mutant Escherichia coli initiator tRNAs in vivo, we previously described a strategy based on the use of tRNA genes carrying an anticodon sequence change from CAU to CUA along with a mutant chloramphenicol acetyltransferase (CAT) gene carrying an initiation codon change from AUG to UAG. Surprisingly, under conditions where the mutant initiator tRNA is optimally active, the CAT gene with the UAG initiation codon produced more CAT protein (3- to 9-fold more depending on the conditions) than the wild-type CAT gene. Here we show that two new mutant CAT genes having GUC and AUC initiation codons also produce more of the CAT protein in the presence of the corresponding mutant initiator tRNAs. These results are most easily understood if assembly of the 30S ribosome-initiator tRNA-mRNA initiation complex in vivo proceeds with the 30S ribosome binding first to the initiator tRNA and then to the mRNA. In cells overproducing the mutant initiator tRNAs, most ribosomes would carry the mutant initiator tRNA and these ribosomes would select the mutant CAT mRNA over the other mRNAs.

The A1 x U72 base pair conserved in eukaryotic initiator tRNAs is important specifically for binding to the eukaryotic translation initiation factor eIF2

The formation of a specific ternary complex between eukaryotic initiation factor 2 (eIF2), the initiator methionyl-tRNA (Met-tRNA), and GTP is a critical step in translation initiation in the cytoplasmic protein-synthesizing system of eukaryotes. We show that the A1 x U72 base pair conserved at the end of the acceptor stem in eukaryotic and archaebacterial initiator methionine tRNAs plays an important role in this interaction. We changed the A1 x U72 base pair of the human initiator tRNA to G1 x C72 and expressed the wild-type and mutant tRNA genes in the yeast Saccharomyces cerevisiae by using constructs previously developed in our laboratory for expression of the human initiator tRNA gene in yeasts. We show that both the wild-type and mutant human initiator tRNAs are aminoacylated well in vivo. We have isolated the wild-type and mutant human initiator tRNAs in substantially pure form, free of the yeast initiator tRNA, and have analyzed their properties in vitro. The G1 x C72 mutation affects specifically the binding affinity of eIF2 for the initiator tRNA. It has no effect on the subsequent formation of 40S or 80S ribosome initiator Met-tRNA-AUG initiation complexes in vitro or on the puromycin reactivity of the Met-tRNA in the 80S initiation complex.

Amber suppression in mammalian cells dependent upon expression of an Escherichia coli aminoacyl-tRNA synthetase gene

As an approach to inducible suppression of nonsense mutations in mammalian and in higher eukaryotic cells, we have analyzed the expression of an Escherichia coli glutamine-inserting amber suppressor tRNA gene in COS-1 and CV-1 monkey kidney cells. The tRNA gene used has the suppressor tRNA coding sequence flanked by sequences derived from a human initiator methionine tRNA gene and has two changes in the coding sequence. This tRNA gene is transcribed, and the transcript is processed to yield the mature tRNA in COS-1 and CV-1 cells. We show that the tRNA is not aminoacylated in COS-1 cells by any of the endogenous aminoacyl-tRNA synthetases and is therefore not functional as a suppressor. Concomitant expression of the E. coli glutaminyl-tRNA synthetase gene results in aminoacylation of the suppressor tRNA and its functioning as a suppressor. These results open up the possibility of attempts at regulated suppression of nonsense codons in mammalian cells by regulating expression of the E. coli glutaminyl-tRNA synthetase gene in an inducible, cell-type specific, or developmentally regulated manner.

Important role of the amino acid attached to tRNA in formylation and in initiation of protein synthesis in Escherichia coli

In attempts to convert an elongator tRNA to an initiator tRNA, we previously generated a mutant elongator methionine tRNA carrying an anticodon sequence change from CAU to CUA along with the two features important for activity of Escherichia coli initiator tRNA in initiation. This mutant tRNA (Mi:2 tRNA) was active in initiation in vivo but only when aminoacylated with methionine by overproduction of methionyl-tRNA synthetase. Here we show that the Mi:2 tRNA is normally aminoacylated in vivo with lysine and that the tRNA aminoacylated with lysine is a very poor substrate for formylation compared with the same tRNA aminoacylated with methionine. By introducing further changes at base pairs 4:69 and 5:68 in the acceptor stem of the Mi:2 tRNA to those found in the E. coli initiator tRNA, we show that change of the U4:A69 base pair to G4:C69 and overproduction of lysyl-tRNA synthetase and methionyl-tRNA transformylase results in partial formylation of the mutant tRNA and activity of the formyllysyl-tRNAs in initiation of protein synthesis. Thus, the G4: C69 base pair contributes toward formylation of the tRNA and protein synthesis in E. coli can be initiated with formyllysine. We also discuss the implications of these and other results on recognition of tRNAs by E. coli lysyl-tRNA synthetase and on competition in cells among aminoacyl-tRNA synthetases.

Escherichia coli initiator tRNA: structure-function relationships and interactions with the translational machinery

We showed previously that the sequence and (or) structural elements important for specifying the many distinctive properties of Escherichia coli initiator tRNA are clustered in the acceptor stem and in the anticodon stem and loop. This paper briefly describes this and reviews the results of some recently published studies on the mutant initiator tRNAs generated during this work. First, we have studied the effect of overproduction of methionyl-tRNA transformylase (MTF) and initiation factors IF2 and IF3 on activity of mutant initiator tRNAs that are defective at specific steps in the initiation pathway. Overproduction of MTF rescued specifically the activity of mutant tRNAs defective in formylation but not mutants defective in binding to the P site. Overproduction of IF2 increased the activity of all mutant tRNAs having the CUA anticodon but not of mutant tRNA having the GAC anticodon. Overproduction of IF3 had no effect on the activity of any of the mutant tRNAs tested. Second, for functional studies of mutant initiator tRNA in vivo, we used a CAU --> CUA anticodon sequence mutant that can initiate protein synthesis from UAG instead of AUG. In contrast with the wild-type initiator tRNA, the mutant initiator tRNA has a 2-methylthio-N6-isopentenyl adenosine (ms2i6A) base modification next to the anticodon. Interestingly, this base modification is now important for activity of the mutant tRNA in initiation. In a miaA strain of E. coli deficient in biosynthesis of ms2i6A, the mutant initiator tRNA is much less active in initiation. The defect is specifically in binding to the ribosomal P site.

Site-directed isotope labeling and FTIR spectroscopy: assignment of tyrosine bands in the bR-->M difference spectrum of bacteriorhodopsin

Fourier transform infrared difference spectroscopy has been used extensively to probe structural changes in bacteriorthodopsin and other retinal proteins. However, the absence of a general method to assign bands to individual chemical groups in a protein has limited the application of this technique. While site-directed mutagenesis has been successful in special cases for such assignments, in general, this approach induces perturbations in the structure and function of the protein, thereby preventing unambiguous band assignments. A new approach has recently been reported (Sonar et al., Nature Struct. Biol. 1 (1994) 512-517) which involves cell-free expression of bacteriorhodopsin and site-directed isotope labeling (SDIL). We have now used this method to re-examine bands assigned in the bR-->M difference spectrum to tyrosine residues. Our results show that out of 11 tyrosines in bR, only Tyr 185 is structurally active. This work further demonstrates the power of SDIL and FTIR to probe conformational changes at the level of individual amino acid residues in proteins.

Sequence of the met-10+ locus of Neurospora crassa: homology to a sequence of unknown function in Saccharomyces cerevisiae chromosome 8

We have determined the sequence of the Neurospora crassa met-10+ gene and its flanking regions, and have isolated and analyzed cDNA clones for this region. We have identified two closely linked genes transcribed in the same orientation. The met-10+ gene is the downstream gene; an open reading frame (ORF) derived from five exons encodes a 475-amino-acid protein. The deduced protein lacks similarity to other characterized proteins. However, it exhibits a strong similarity to the product of an ORF of unknown function on Saccharomyces cerevisiae chromosome 8. This sequence similarity suggests functional equivalence and should facilitate identification of the function of met-10+ using gene disruptions in S. cerevisiae.

Mutants of Escherichia coli initiator tRNA defective in initiation. Effects of overproduction of methionyl-tRNA transformylase and the initiation factors IF2 and IF3

We describe the effects of overproduction of methionyl-tRNA transformylase and initiation factors IF2 and IF3 on the activity, in vivo, of initiator tRNA mutants defective at specific steps of the initiation process in protein synthesis. The activity of the U35A36/G72 and U35A36/G72G73 mutants, which are defective in formylation, was increased by overproduction of methionyl-tRNA transformylase. In contrast, the activity of the C30:G40/U35A36 mutant, which is formylated normally but is defective in binding to the ribosomal P site, was not increased. Overproduction of IF2 had a strong stimulatory effect on the activity of virtually all the mutants carrying the U35A36 anticodon sequence change, including the U35A36, U35A36/G72, U35A36/G72G73, and the C30:G40/U35A36 mutants. In cells overproducing IF2, the amount of protein made by translation of a mutant mRNA, which uses the U35A36 mutant initiator tRNA, is severalfold higher than that made by translation of a wild type mRNA. We discuss the possible implications of this result on overproduction of proteins and on the order of assembly of the 30 S ribosome.mRNA.fMet-tRNA initiation complex in Escherichia coli. Over-production of IF3 did not affect the initiator activity of any of the tRNA mutants studied.

An anticodon sequence mutant of Escherichia coli initiator tRNA: possible importance of a newly acquired base modification next to the anticodon on its activity in initiation

Initiator tRNAs from eubacteria and chloroplasts lack a base modification next to the anticodon. This is in contrast to virtually all other tRNAs from these sources. We show that a mutant Escherichia coli initiator tRNA which has an anticodon sequence change from CAU to CUA now has a 2-methylthio-N6-(delta 2-isopentenyl)adenosine (ms2i6A) modification, produced by posttranscriptional modification of A, next to the anticodon. This newly acquired base modification may be important for the function of the mutant tRNA in initiation. In a miaA mutant strain of E. coli defective in biosynthesis of ms2i6A, the mutant initiator tRNA is 10- to 12-fold less active in initiation. The mutant tRNA is aminoacylated and formylated normally in the miaA strain. Thus, the absence of the base modification affects the activity of the mutant tRNA at a step subsequent to its formylation.

Site-directed isotope labeling and ATR-FTIR difference spectroscopy of bacteriorhodopsin: the peptide carbonyl group of Tyr 185 is structurally active during the bR-->N transition

The largest secondary structural change occurs in the bacteriorhodopsin (bR) photocycle during the M-->N transition. In this work site-directed isotope labeling (SDIL) and attenuated total reflection Fourier transform infrared (ATR-FTIR) difference spectroscopy were used to investigate this conformational change. L-Tyrosine containing a 13C isotope at the carbonyl carbon was selectively incorporated at Tyr 57, Tyr 147, and Tyr 185 by SDIL. This involves the cell-free expression of bR in the presence of Escherichia coli suppressor tRNA(CUATyr) aminoacylated with L-[1-13C]Tyr. ATR-FTIR difference spectroscopy reveals that of the 11 tyrosines, only the peptide carbonyl group of Tyr 185 undergoes a significant structural change during the bR-->N transition. Along with other spectroscopic evidence, this result suggests that the Tyr 185-Pro 186 region of the protein is structurally active and may function as a hinge which facilitates the tilt of the cytoplasmic portion of the F-helix in bacteriorhodopsin during the M-->N transition.

NMR analysis of tRNA acceptor stem microhelices: discriminator base change affects tRNA conformation at the 3' end

An important step in initiation of protein synthesis in Escherichia coli is the specific formylation of the initiator methionyl-tRNA (Met-tRNA) by Met-tRNA transformylase. The determinants for formylation are clustered mostly in the acceptor stem of the initiator tRNA. Here we use NMR spectroscopy to characterize the conformation of two RNA microhelices, which correspond to the acceptor stem of mutants of E. coli initiator tRNA and which differ only at the position corresponding to the "discriminator base" in tRNAs. One of the mutant tRNAs is an extremely poor substrate for Met-tRNA transformylase, whereas the other one is a much better substrate. We show that one microhelix forms a structure in which its 3'-ACCA sequence extends the stacking of the acceptor stem. The other microhelix forms a structure in which its 3'-UCCA sequence folds back such that the 3'-terminal A22 is in close proximity to G1. These results highlight the importance of the discriminator base in determining tRNA conformation at the 3' end. They also suggest a correlation between tRNA structure at the 3' end and its recognition by Met-tRNA transformylase.

Site-directed isotope labelling and FTIR spectroscopy of bacteriorhodopsin

Insight into integral membrane proteins function is presently limited by the difficulty of producing three-dimensional crystals. In addition, X-ray structures of proteins normally do not provide information about the protonation state and structural changes of individual residues. We report here the first use of site-directed isotope labelling and Fourier transform infrared (FTIR) difference spectroscopy to detect structural changes at the level of single residues in an integral membrane protein. Two site-directed isotope labeled (SDIL) tyrosine analogues of bacteriorhodopsin were produced which exhibit normal activity. FTIR spectroscopy shows that out of 11 tyrosines, only Tyr 185 is structurally active during the early photocycle and may be part of a proton wire.

Initiator transfer RNAs

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The role of nucleotides conserved in eukaryotic initiator methionine tRNAs in initiation of protein synthesis

Mutant human initiator tRNA genes carrying changes in each of the three features unique to eukaryotic initiator tRNAs have been constructed, and introduced into CV-1 monkey kidney cells using SV40 virus vectors. The mutant tRNA genes are expressed, and the mutant tRNAs can all be aminoacylated with both rabbit liver and Escherichia coli methionyl-tRNA synthetases. Based on aminoacylation levels, the tRNAs are expressed to 5-15-fold over the level of endogenous initiator tRNA. The activity of the mutant [35S]methionyl-tRNAs in initiation was studied in rabbit reticulocyte and wheat germ cell-free protein synthesis systems programmed with various mRNAs. Initiation is studied by using a mRNA that codes for a protein whose N-terminal methionine is stable and not removed by methionine aminopeptidase. Changing the A1:U72 base pair to a G1:C72 base pair greatly reduced activity of the tRNA in initiation. Changing the three consecutive G:C base pairs (G29G30G31:C39C40C41) in the anticodon stem to those found in elongator methionine tRNA also reduced initiation activity. Interestingly, changing the A54 and A60 residues in loop IV to T54 and U60 had less of an effect on activity. The tRNA with changes in all three conserved features had virtually no activity in initiation.

The discriminator base influences tRNA structure at the end of the acceptor stem and possibly its interaction with proteins

For many tRNAs, the discriminator base preceding the CCA sequence at the 3' end is important for aminoacylation. We show that the discriminator base influences the stability of the 1.72 base pair onto which it is stacked. Mutations of the discriminator base from adenosine to cytidine or uridine make the cytidine residue in the C1-G72 base pair of mutant Escherichia coli initiator tRNAs more reactive toward sodium bisulfite, the single-strand-specific reagent. The activity of the enzyme Met-tRNA transformylase toward these and other mutant initiator tRNAs is also consistent with destabilization of the 1.72 base pair in vitro and in vivo. By influencing the strength of the 1.72 base pair, the discriminator base could affect the energetic cost of opening the base pair and modulate the structure of the tRNA near the site of aminoacylation. For some aminoacyl-tRNA synthetases and other proteins that interact with tRNA, these factors could be important for specific recognition and/or formation of the transition state during catalysis.

Saccharomyces cerevisiae cytoplasmic tyrosyl-tRNA synthetase gene. Isolation by complementation of a mutant Escherichia coli suppressor tRNA defective in aminoacylation and sequence analysis

Exploiting differences in tRNA recognition between prokaryotic and eukaryotic tyrosyl-tRNA synthetases (TyrRSs), we have isolated the gene for the cytoplasmic TyrRS of Saccharomyces cerevisiae by functional complementation in Escherichia coli of a mutant E. coli tRNA. The tRNA, derived from the E. coli initiator tRNA with changes to allow suppression of amber termination codons, is poorly aminoacylated in E. coli and hence, is only a weak amber suppressor. The same tRNA functions as a good suppressor in S. cerevisiae and is aminoacylated with tyrosine by yeast extracts. We expressed a yeast cDNA library in an E. coli strain carrying the mutant tRNA gene and several genes with amber mutations. cDNA clones were isolated which increased suppression and levels of aminoacylation of the mutant tRNA. Characterization of the gene identified a methionine-initiated open reading frame encoding a protein of 394 amino acids. Expression of this protein in E. coli demonstrated that tyrosine was incorporated during suppression and that yeast cytoplasmic TyrRS activity was produced. Yeast cytoplasmic TyrRS has sequences typical of class I aminoacyl-tRNA synthetases, but only weak overall sequence similarity to the corresponding eubacterial and mitochondrial TyrRSs. However, many of the residues known to line the tyrosyl-adenylate-binding pocket of the Bacillus stearothermophilus enzyme can be aligned in the yeast sequence. These include the aspartic acid and tyrosine residues thought to contact the tyrosine side chain to provide substrate specificity.

Developmental regulation of the gene for formate dehydrogenase in Neurospora crassa

We have isolated and characterized a gene, fdh, from Neurospora crassa which is developmentally regulated and which produces formate dehydrogenase activity when expressed in Escherichia coli. The gene is closely linked (less than 0.6 kb apart) to the leu-5 gene encoding mitochondrial leucyl-tRNA synthetase; the two genes are transcribed convergently from opposite strands. The expression patterns of these genes differ: fdh mRNA is found only during conidiation and early germination and is not detectable during mycelial growth, while leu-5 mRNA appears during germination and mycelial growth. The structure of the fdh gene was determined from the sequence of cDNA and genomic DNA clones and from mRNA mapping studies. The gene encodes a 375-amino-acid-long protein with sequence similarity to NAD-dependent dehydrogenases of the E. coli 3-phosphoglycerate dehydrogenase (serA gene product) subfamily. In particular, there is striking sequence similarity (52% identity) to formate dehydrogenase from Pseudomonas sp. strain 101. All of the residues thought to interact with NAD in the crystal structure of the Pseudomonas enzyme are conserved in the N. crassa enzyme. We have further shown that expression of the N. crassa gene in E. coli leads to the production of formate dehydrogenase activity, indicating that the N. crassa gene specifies a functional polypeptide.

From elongator tRNA to initiator tRNA

We show that the two most important properties needed for a tRNA to function in initiation in Escherichia coli are its ability to be formylated and its ability to bind to the ribosomal P site. This conclusion is based on conversion of two different elongator tRNAs to ones that can act as initiators in E. coli. We transplanted the features unique to E. coli and eubacterial initiator tRNAs to E. coli elongator methionine tRNA (tRNA(Met)) along with an anticodon sequence change and analyzed their activities in initiation in E. coli. Introduction of a C1.A72 mismatch at the end of the acceptor stem of tRNA(Met), which generates the minimal features necessary for formylation, produces a tRNA with very low activity in initiation. Subsequent introduction of three consecutive G.C base pairs at the bottom of the anticodon stem, which is necessary for ribosomal P site binding, produces a tRNA with significant activity in initiation. Furthermore, introduction of the features necessary for formylation and for ribosomal P site binding into E. coli elongator glutamine tRNA produces a tRNA that initiates protein synthesis in E. coli.

Relationship between the structure and function of Escherichia coli initiator tRNA

Through functional studies of mutant tRNAs, we have identified sequence and/or structural features important for specifying the many distinctive properties of E coli initiator tRNA. Many of the mutant tRNAs contain an anticodon sequence change from CAU-->CUA and are now substrates for E coli glutaminyl-tRNA synthetase (GlnRS). We describe here the effect of further mutating the discriminator base 73 and nucleotide 72 at the end of the acceptor stem on: i) recognition of the mutant tRNAs by E coli GlnRS; ii) recognition by E coli methionyl-tRNA transformylase; and iii) activity of the mutant tRNAs in initiation in E coli. For GlnRS recognition, our results are, in general, consistent with interactions found in the crystal structure of the E coli GlnRS-glutamine tRNA complex. The results also support our previous conclusion that formylation of initiator tRNA is important for its function in initiation.

Escherichia coli B lacks one of the two initiator tRNA species present in E. coli K-12

We show that the metY locus which specifies tRNA(2fMet) in Escherichia coli K-12 specifies tRNA(1fMet) in E. coli B. This conclusion is based on results of Southern blot analysis of E. coli B and K-12 DNAs and on polymerase chain reaction amplification, cloning, and sequencing of an approximately 200-bp region of DNA corresponding to the metY loci of E. coli B and E. coli K-12. We also show that the metY locus of E. coli B is transcriptionally active. E. coli strains transformed with the multicopy plasmid vector pUC19 carrying the metY locus of E. coli B overproduce tRNA(1fMet) in E. coli B and E. coli K-12 in contrast to strains transformed with pUC19 carrying the corresponding locus from E. coli K-12, which overproduce tRNA(2fMet).

Role of methionine and formylation of initiator tRNA in initiation of protein synthesis in Escherichia coli

We showed recently that a mutant of Escherichia coli initiator tRNA with a CAU-->CUA anticodon sequence change can initiate protein synthesis from UAG by using formylglutamine instead of formylmethionine. We further showed that coupling of the anticodon sequence change to mutations in the acceptor stem that reduced Vmax/Km(app) in formylation of the tRNAs in vitro significantly reduced their activity in initiation in vivo. In this work, we have screened an E. coli genomic DNA library in a multicopy vector carrying one of the mutant tRNA genes and have found that the gene for E. coli methionyl-tRNA synthetase (MetRS) rescues, partially, the initiation defect of the mutant tRNA. For other mutant tRNAs, we have examined the effect of overproduction of MetRS on their activities in initiation and their aminoacylation and formylation in vivo. Some but not all of the tRNA mutants can be rescued. Those that cannot be rescued are extremely poor substrates for MetRS or the formylating enzyme. Overproduction of MetRS also significantly increases the initiation activity of a tRNA mutant which can otherwise be aminoacylated with glutamine and fully formylated in vivo. We interpret these results as follows. (i) Mutant initiator tRNAs that are poor substrates for MetRS are aminoacylated in part with methionine when MetRS is overproduced. (ii) Mutant tRNAs aminoacylated with methionine are better substrates for the formylating enzyme in vivo than mutant tRNAs aminoacylated with glutamine. (iii) Mutant tRNAs carrying formylmethionine are significantly more active in initiation than those carrying formylglutamine. Consequently, a subset of mutant tRNAs which are defective in formylation and therefore inactive in initiation when they are aminoacylated with glutamine become partially active when MetRS is overproduced.

Striking effects of coupling mutations in the acceptor stem on recognition of tRNAs by Escherichia coli Met-tRNA synthetase and Met-tRNA transformylase

We measured kinetic parameters in vitro and directly analyzed aminoacylation and formylation levels in vivo to study recognition of Escherichia coli initiator tRNA mutants by E. coli Met-tRNA synthetase and Met-tRNA transformylase. We show that, in addition to the anticodon sequence, mutations in the "discriminator" base A73 also affect aminoacylation. An A73----U change has a small effect, but a change to G73 or C73 significantly lowers Vmax/Kappm for in vitro aminoacylation and leads to appreciable accumulation of uncharged tRNA in vivo. Significantly, coupling of the G73 mutation with G72, a neighboring-base mutation, results in a tRNA essentially uncharged in vivo. Coupling of C73 and U73 mutations with G72 does not have such an effect. Elements crucial for Met-tRNA transformylase recognition of tRNAs are located at the end of the acceptor stem. These elements include a weak base pair or a mismatch between nucleotides (nt) 1 and 72 and base pairs 2.71 and 3.70. The natures of nt 1 and 72 are less important than the fact that they do not form a strong Watson-Crick base pair. Interestingly, the negative effect of a C.G base pair between nt 1 and 72 is suppressed by mutation of the neighboring nucleotide A73 to either C73 or U73. The presence of C73 or U73 could destabilize the C1.G72 base pair at the end of an RNA helix. Thus, in some tRNAs, the discriminator base could affect stability of the base pair between nt 1 and 72 and thereby the structure of tRNA at the end of the acceptor stem.

Direct analysis of aminoacylation levels of tRNAs in vivo. Application to studying recognition of Escherichia coli initiator tRNA mutants by glutaminyl-tRNA synthetase

We describe the use of a gel electrophoretic method for measuring the levels of aminoacylation in vivo of mutant Escherichia coli initiator tRNAs, which are substrates for E. coli glutaminyl-tRNA synthetase (GlnRS) due to an anticodon sequence change. Using this method, we have compared the effects of introducing further mutations in the acceptor stem, at base pairs 1:72, 2:71, and 3:70 and discriminator base 73, on the recognition of these tRNAs by E. coli GlnRS in vitro and in vivo. The effects of the acceptor stem mutations on the kinetic parameters for aminoacylation of the mutant tRNAs in vitro are consistent with interactions seen between this region of tRNA and GlnRS in the crystal structure of tRNA(Gln). GlnRS complex. Except for one mutant, the observed levels of aminoacylation of the mutant tRNAs in vivo agree with those expected on the basis of the kinetic parameters obtained in vitro. We have also measured the relative amounts of aminoacyl-tRNAs for the various mutants and their activities in suppression of an amber codon in vivo. We find that there is, in general, a good correlation between the relative amounts of aminoacyl-tRNAs and their activities in suppression.

Mutants of Escherichia coli initiator tRNA that suppress amber codons in Saccharomyces cerevisiae and are aminoacylated with tyrosine by yeast extracts

We recently described mutants of Escherichia coli initiator tRNA that suppress amber termination codons (UAG) in E. coli. These mutants have changes in the anticodon sequence (CAU----CUA) that allow them to read the amber codon and changes in the acceptor stem that allow them to bind to the ribosomal aminoacyl (A) site. We show here that a subset of these mutants suppress amber codons in Saccharomyces cerevisiae and that they are aminoacylated with tyrosine by yeast extracts. Analysis of a number of mutants as substrates for yeast tyrosyl-tRNA synthetase has led to identification of the C1.G72 base pair and the discriminator base A73, conserved in all eukaryotic cytoplasmic and archaebacterial tyrosine tRNAs, as being important for recognition. Our results suggest that the C1.G72 base pair and the discriminator base, in addition to the anticodon nucleotides previously identified [Bare, L.A. & Uhlenbeck, O.C. (1986) Biochemistry 25, 5825-5830] as important in yeast tyrosyl-tRNA synthetase recognition, may comprise the critical identity determinants in yeast tyrosine tRNA.

Structural and sequence elements important for recognition of Escherichia coli formylmethionine tRNA by methionyl-tRNA transformylase are clustered in the acceptor stem

We show that the structure and/or sequence of the first three base pairs at the end of the amino acid acceptor stem of Escherichia coli initiator tRNA and the discriminator base 73 are important for its formylation by E. coli methionyl-tRNA transformylase. This conclusion is based on mutagenesis of the E. coli initiator tRNA gene followed by measurement of kinetic parameters for formylation of the mutant tRNAs in vitro and function in protein synthesis in vivo. The first base pair found at the end of the amino acid acceptor stem in all other tRNAs is replaced by a C.A. "mismatch" in E. coli initiator tRNA. Mutation of this C.A. to U:A, a weak base pair, or U.G., a mismatch, has little effect on formylation, whereas mutation to C:G, a strong base pair, has a dramatic effect lowering Vmax/Kappm by 495-fold. Mutation of the second basepair G2:C71 to U2:A71 lowers Vmax/Kappm by 236-fold. Replacement of the third base-pair C3:G70 by U3:A70, A3:U70, or G3:C70 lowers Vmax/Kappm by about 67-, 27-, and 30-fold, respectively. Changes in the rest of the acceptor stem, dihydrouridine stem, anticodon stem, anticodon sequence, and T psi C stem have little or no effect on formylation.

Mutants of initiator tRNA that function both as initiators and elongators

We describe the effect of mutations in the acceptor stem of Escherichia coli initiator tRNA on its function in vivo. The acceptor stem mutations were coupled to mutations in the anticodon sequence from CAU----CUA to allow functional studies on the mutant tRNAs in initiation and in elongation in vivo. We show that, with one exception, there is a good correlation between the kinetic parameters for formylation of the mutant tRNAs in vitro (preceding paper, Lee, C.P., Seong, B. L., and RajBhandary, U.L. (1991) J. Biol. Chem. 266, 18012-18017) and their activity in initiation in vivo. These results suggest an important role for formylation of initiator tRNA in its function in initiation, at least when it is aminoacylated with glutamine as is the case with the mutant tRNAs used here. Mutant tRNAs that have a base pair between nucleotides 1 and 72 at the top of the acceptor stem function as elongators, as analyzed by their ability to suppress an amber mutation in the E. coli beta-galactosidase gene. One of these mutants is also quite active in initiation. Thus, activities of a tRNA in initiation and elongation steps of protein synthesis are not mutually exclusive. Using a mRNA with two in frame UAG codons, we show that this mutant tRNA can both initiate protein synthesis from the upstream UAG and suppress the down-stream UAG. We discuss the potential use of tRNAs with such "dual" functions in tightly regulated expression of genes for proteins in E. coli.

Construction, stable transformation, and function of an amber suppressor tRNA gene in Drosophila melanogaster

Drosophila melanogaster strains with a stably incorporated amber suppressor tRNA gene have been generated. A tRNATyr gene was site specifically mutated to produce an anticodon sequence that recognizes the amber codon and then introduced into Drosophila by using P-element-mediated transformation. Transformants from four integration events were recovered. Two integrations resulted in both male and female sterility, whereas the other two resulted in male sterility but female fertility. Strains derived from the two female-fertile integration events were shown to have a low level of amber-suppressing activity by their ability to suppress an amber mutation in a chloramphenicol acetyltransferase gene.

Suppression of amber codons in vivo as evidence that mutants derived from Escherichia coli initiator tRNA can act at the step of elongation in protein synthesis

The absence of a Watson-Crick base pair at the end of the amino acid acceptor stem is one of the features which distinguishes prokaryotic initiator tRNAs as a class from all other tRNAs. We show that this structural feature prevents Escherichia coli initiator tRNA from acting as an elongator in protein synthesis in vivo. We generated a mutant of E. coli initiator tRNA in which the anticodon sequence is changed from CAU to CUA (the T35A36 mutant). This mutant tRNA has the potential to read the amber termination codon UAG. We then coupled this mutation to others which change the C1.A72 mismatch at the end of the acceptor stem to either a U1:A72 base pair (T1 mutant) or a C1:G72 base pair (G72 mutant). Transformation of E. coli CA274 (HfrC Su- lacZ125am trpEam) with multicopy plasmids carrying the mutant initiator tRNA genes show that mutant tRNAs carrying changes in both the anticodon sequence and the acceptor stem suppress amber codons in vivo, whereas mutant tRNA with changes in the anticodon sequence alone does not. Mutant tRNAs with the above anticodon sequence change are aminoacylated with glutamine in vitro. Measurement of kinetic parameters for aminoacylation by E. coli glutaminyl-tRNA synthetase show that both the nature of the base pair at the end of the acceptor stem and the presence or absence of a base pair at this position can affect aminoacylation kinetics. We discuss the implications of this result on recognition of tRNAs by E. coli glutaminyl-tRNA synthetase.