Mischarging mutants of Su+2 glutamine tRNA in E. coli. I. Mutations near the anticodon cause mischarging

In order to select the mischarging mutants of Su+2 glutamine tRNA, auxotrophic amber mutants of E. coli K12 which cannot be suppressed particularly by Su+2 were screened. By utilizing these mutants, cysam235 and metam3, several tens of mischarging mutants of Su+2 were isolated, as those conferring altered suppression patterns for a set of tester amber mutants of bacteria and phages. Nucleotide sequence analysis revealed that the mutation sites were found to be exclusively at psi 37 residue located at the 3'-end of anticodon loop, changing it to either A37 or C37. These mutants were obtained as those suppressing cysam235, and not metam3. From these, secondary mutants were selected. In these mutants suppression patterns were further altered by the additional base substitutions, capable of suppressing metam3. Such mutants were obtained exclusively from A37 and not from C37 mutant tRNA. Additional mutations to A37 were found to be either A29 or C38, which are located at the lowermost two base pairs in anticodon stem. The mischarging sites in Su+2 glutamine tRNA locate in the newly detected region of tRNA, differing from the previous case of Su+3 tyrosine or Su+7 tryptophan tRNAs. Implication of this finding is discussed on L-shaped tRNA molecule in relation to aminoacyl-tRNA synthetase recognition. Suppression patterns given by the double-mutants, A37A29 and A37C38, were consistent with the observation that the mutant tRNAs interact with tryptophanyl-tRNA synthetase.     

Mutational identification of an essential tryptophan in tryptophanyl-tRNA synthetase of Bacillus subtilis.

The strongly conserved single tryptophan residue, Trp92, in Bacillus subtilis tryptophanyl-tRNA synthetase has been mutagenized via site direction singly into Gln, Ala, and Phe. All three mutant enzymes were inactive toward the catalysis of tRNA tryptophanylation. The Trp92----Phe mutant has been subcloned into the high expression plasmid pKK223-3 to yield the recombinant plasmid pKSW-F92. Growth of bacteria carrying the latter plasmid made possible the purification of the mutant TrpRS-F92 enzyme to homogeneity. This mutant enzyme was deficient in ultraviolet absorbance and fluorescence relative to the wild type enzyme and inactive in the partial reaction of Trp-activation as well as the overall reaction of tRNA tryptophanylation. Furthermore, unlike the wild type B. subtilis trpS gene, the mutant trpS-F92 gene upon transformation into Escherichia coli trpS 10343 failed to complement the temperature sensitive trpS mutation of the host cells. Trp92 therefore represents an essential residue both in vitro and in vivo for the function of the tryptophanyl-tRNA synthetase.     

Synthetase competition and tRNA context determine the in vivo identify of tRNA discriminator mutants.

The discriminator nucleotide (position 73) in tRNA has long been thought to play a role in tRNA identity as it is the only variable single-stranded nucleotide that is found near the site of aminoacylation. For this reason, a complete mutagenic analysis of the discriminator in three Escherichia coli amber suppressor tRNA backgrounds was undertaken; supE and supE-G1C72 glutamine tRNAs, gluA glutamate tRNA and supF tyrosine tRNA. The effect of mutation of the discriminator base on the identity of these tRNAs in vivo was assayed by N-terminal protein sequencing of E. coli dihydrofolate reductase, which is the product of suppression by the mutated amber suppressors, and confirmed by amino acid specific suppression experiments. In addition, suppressor efficiency assays were used to estimate the efficiency of aminoacylation in vivo. Our results indicate that the supE glutamine tRNA context can tolerate multiple mutations (including mutation of the discriminator and first base-pair) and still remain predominantly glutamine-accepting. Discriminator mutants of gluA glutamate tRNA exhibit increased and altered specificity probably due to the reduced ability of other synthetases to compete with glutamyl-tRNA synthetase. In the course of these experiments, a glutamate-specific mutant amber suppressor, gluA-A73, was created. Finally, in the case of supF tyrosine tRNA, the discriminator is an important identity element with partial to complete loss of tyrosine specificity resulting from mutation at this position. It is clear from these experiments that it may not be possible to assign a specific role in tRNA identity to the discriminator. The identity of a tRNA in vivo is determined by competition among aminoacyl-tRNA synthetases, which is in turn modulated by the nucleotide substitution as well as the tRNA context.     

Temperature-induced derepression of tryptophan biosynthesis in a tryptophanyl-transfer ribonucleic acid synthetase mutant of Bacillus subtilis

A tryptophanyl-transfer ribonucleic acid (tRNA) synthetase (l-tryptophan: tRNA ligase adenosine monophosphate, EC 6.1.1.2) mutant (trpS1) of Bacillus subtilis is derepressed for enzymes of the tryptophan biosynthetic pathway at temperatures which reduce the growth rate but still allow exponential growth. Derepression of anthranilate synthase in a tryptophan-supplemented medium (50 mug/ml) is maximal at 36 C, and the differential rate of synthesis is 600- to 2,000-fold greater than that of the wild-type strain or trpS1 revertants. A study of the derepression pattern in the mutant and its revertants indicates that the 5-fluorotryptophan recognition site of the tryptophanyl-tRNA synthetase is an integral part of the repression mechanism. Evidence for a second locus, unlinked to the trpS1 locus, which functions in the repression of tryptophan biosynthetic enzymes is presented.     

TRNA2Gln Su+2 mutants that increase amber suppression.

We selected mutants of lambda pSu+2 which had an increased ability to suppress on Escherichia coli trp B9601 amber mutation on translationally stringent rpsL594 streptomycin-resistant ribosomes. tRNA2Gin Su+2 molecules produced from eight independent mutants were purified, and their ribonucleic acid sequences were determined. Two types of mutations were mapped to the tRNA2Gin Su+2(glnV) gene by this method. Both altered the pseudouridine at position 37 of the tRNA anticodon loop. Seven of the isolates were transitions (pseudouridine to cytosine), and one was a transversion (pseudouridine to adenine). These mutations resulted in Su+ transfer ribonucleic acid molecules that exhibited higher transmission coefficients than their parent Su+2 transfer ribonucleic acids. As judged by their suppressor spectra on T4 amber mutants, which were almost identical to that of Su+2, the two mutant Su+ transfer ribonucleic acids inserted glutamine at amber sites.     

Temperature-sensitive repression of the tryptophan operon in Escherichia coli

Mutants of Escherichia coli exhibiting temperature-sensitive repression of the tryptophan operon have been isolated among the revertants of a tryptophan auxotroph, trpS5, that produces an altered tryptophanyl transfer ribonucleic acid (tRNA) synthetase. Unlike the parental strain, these mutants grew in the absence of tryptophan at high but not at low temperature. When grown at 43.5 C with excess tryptophan (repression conditions), they produced 10 times more anthranilate synthetase than when grown at 36 C or lower temperatures. Similar, though less striking, temperature-sensitivity was observed with respect to the formation of tryptophan synthetase. Transduction mapping by phage P1 revealed that these mutants carry a mutation cotransducible with thr at 60 to 80%, in addition to trpS5, and that the former mutation is primarily responsible for the temperature-sensitive repression. These results suggest that the present mutants represent a novel type of mutation of the classical regulatory gene trpR, which probably determines the structure of a protein involved in repression of the tryptophan operon. In agreement with this conclusion, tRNA of several trpR mutants was found to be normal with respect to its tryptophan acceptability. It was also shown that the trpS5 allele, whether present in trpR or trpR(+) strains, produced appreciably higher amounts of anthranilate synthetase than the corresponding trpS(+) strains under repression conditions. This was particularly true at higher temperatures. These results provide further evidence for our previous conclusion that tryptophanyl-tRNA synthetase is somehow involved in repression of this operon.     

Identity elements and aminoacylation of plant tRNATrp.

Mutation of the Arabidopsis thaliana tRNA (Trp)(CCA) anticodon or of the A73 discriminator base greatly diminishes in vitro aminoacylation with tryptophan, indicating the importance of these nucleotides for recognition by the plant tryptophanyl-tRNA synthetase. Mutation of the tRNA (Trp)(CCA) anticodon to CUA so as to translate amber nonsense codons permits tRNA (Trp)(CCA) to be aminoacylated by A.thaliana lysyl-tRNA synthetase. Thus, translational suppression by tRNA (TRP)(CCA) observed in plant cells includes significant incorporation of lysine into protein.     

Search for revertants of the glutamine mischarging mutans of Escherichia coli su+3 tyrosine suppressor tRNA that are able to insert tyrosine at the site of amber mutation.

We have isolated a bacterial amber mutation (nadam) that is suppressed by the tyrosine inserting suppressor su+3 but not by the glutamine (su+2, su+3 A1, su+3 G82 and su+3 A1G82), serine (su+1) and leucine (su+6) inserting suppressors. The su+7 suppressor which inserts glutamine and tryptophan also suppresses this mutation indicating that tryptophan, in addition to tyrosine, is accepted at the site of amber mutation. We have used this amber mutation to search for revertants of the su+3 glutamine mischarging mutants su+3 A1, su+3 G82 and su+3 A1G82 that are able to insert tyrosine at the site of amber mutation. Two types of revertants were found in the case of su+3 A1. One type corresponding to the true revertant A1 leads to G, and the other to the second site revertants C81 leads to U (A1U81). The A1U81 revertant has been shown to insert both glutamine and tyrosine at the site of amber mutation. Only true revertants (G82 leads to A) were obtained when su+3 G82 was analyzed. No revertants were obtained in the case of the su+3 A1G82. These results are discussed in relation to aminoacyl-tRNA recognition.     

Dual specificity of su+7 tRNA. Evidence for translational discrimination

The su⁺7 amber suppressor of Escherichia coli is a mutant tRNA^Trp that translates UAG codons as glutamine. Nevertheless, the purified su⁺7 tRNA can be charged with either glutamine or tryptophan. Aminoacylation kinetics in vitro suggest that the tRNA should be acylated with equal amounts of glutamine and tryptophan in vivo. The predominance of the glutamine specificity of the suppressor is therefore potentially anomalous. We can find no selective deacylation of tryptophanyl-su⁺7 tRNA by glutaminyl-tRNA synthetase, tryptophanyl-tRNA synthetase, or any other cellular element. Furthermore, as predicted, nearly equal amounts of glutaminyl and tryptophanyl-su⁺7 tRNA are actually detected in aminoacyl-tRNA extracted from growing cells. We conclude that the translational apparatus somehow discriminates against tryptophanyl-su⁺7 tRNA at a step after synthesis of the two aminoacyl-tRNAs.     

Mischarging single and double mutants of Escherichia coli sup3 tyrosine transfer RNA

Mischarging mutants of Escherichia coli sup3 tyrosine transfer RNA have been isolated by selecting for suppression of bacterial amber mutations not suppressed by sup3. Five of the mutants have single base changes in the amino acid acceptor stem (A1, A2, U80, U81 and G82). Mutants A1 and A2 are weak thermosensitive suppressors from which thermostable derivatives have been isolated. Some of these derivatives affect the amount of tRNA synthesized but not the sequence (precursor or promoter mutations), and others are double mutants A1U81 and A2U80. The latter mutant does not mischarge. The efficiency of suppression of A1 and A2 can also be increased by recombination events that lead to duplication and triplication of the suppressor gene.The amino acid inserted by some of these mutants at the amber site has been determined. Mutant A1 inserts glutamine, while U81 and A1U81 insert both glutamine and tyrosine.Taken together the results show that the terminal part of the amino acid acceptor stem has an important role in the specificity of aminoacylation by the glutamine and tyrosine synthetase.     

In vitro conversion of a methionine to a glutamine-acceptor tRNA

A derivative of Escherichia coli tRNAfMet containing an altered anticodon sequence, CUA, has been enzymatically synthesized in vitro. The variant tRNA was prepared by excision of the normal anticodon, CAU, in a limited digestion of intact tRNAfMet with RNase A, followed by insertion of the CUA sequence into the anticodon loop with T4 RNA ligase and polynucleotide kinase. The altered methionine tRNA showed a large enhancement in the rate of aminoacylation by glutaminyl-tRNA synthetase and a large decrease in the rate of aminoacylation by methionyl-tRNA synthetase. Measurement of kinetic parameters for the charging reaction by the cognate and noncognate enzymes revealed that the modified tRNA is a better acceptor for glutamine than for methionine. The rate of mischarging is similar to that previously reported for a tryptophan amber suppressor tRNA containing the anticodon CUA, su+7 tRNATrp, which is aminoacylated with glutamine both in vivo and in vitro [Yaniv, M., Folk, W. R., Berg, P., & Soll, L. (1974) J. Mol. Biol. 86, 245-260; Yarus, M., Knowlton, R. E., & Soll, L. (1977) in Nucleic Acid-Protein Recognition (Vogel, H., Ed.) pp 391-408, Academic Press, New York]. The present results provide additional evidence that the specificity of aminoacylation by glutaminyl-tRNA synthetase is sensitive to small changes in the nucleotide sequence of noncognate tRNAs and that uridine in the middle position of the anticodon is involved in the recognition of tRNA substrates by this enzyme.     

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.     

Neurospora Mutant Deficient in Tryptophanyl-Transfer Ribonucleic Acid Synthetase Activity

A tryptophan auxotroph of Neurospora crassa, trp-5, has been characterized as a mutant with a deficient tryptophanyl-transfer ribonucleic acid (tRNA) synthetase (EC 6.1.1.2) activity. When assayed by tryptophanyl-tRNA formation, extracts of the mutant have less than 5% of the wild-type specific activity. The adenosine triphosphate-pyrophosphate exchange activity is at about half the normal level. In the mutant derepressed levels of anthranilate synthetase and tryptophan synthetase were associated with free tryptophan pools equal to or higher than those found in the wild type. We conclude that a product of the normal tryptophanyl-tRNA synthetase, probably tryptophanyl-tRNA, rather than free tryptophan, participates in the repression of the tryptophan biosynthetic enzymes.     

Construction of Escherichia coli amber suppressor tRNA genes. III. Determination of tRNA specificity

Using synthetic oligonucleotides, we have constructed a collection of Escherichia coli amber suppressor tRNA genes. In order to determine their specificities, these tRNAs were each used to suppress an amber (UAG) nonsense mutation in the E. coli dihydrofolate reductase gene fol. The mutant proteins were purified and subjected to N-terminal sequence analysis to determine which amino acid had been inserted by the suppressor tRNAs at the position of the amber codon. The suppressors can be classified into three groups on the basis of the protein sequence information. Class I suppressors, tRNA(CUAAla2), tRNA(CUAGly1), tRNA(CUAHisA), tRNA(CUALys) and tRNA(CUAProH), inserted the predicted amino acid. The class II suppressors, tRNA(CUAGluA), tRNA(CUAGly2) and tRNA(CUAIle1) were either partially or predominantly mischarged by the glutamine aminoacyl tRNA synthetase. The class III suppressors, tRNA(CUAArg), tRNA(CUAAspM), tRNA(CUAIle2), tRNA(CUAThr2), tRNA(CUAMet(m)) and tRNA(CUAVal) inserted predominantly lysine.     

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.     

Regulation of nitrogen fixation. Nitrogenase-derepressed mutants of Klebsiella pneumoniae.

1. A new procedure is described for selecting nitrogenase-derepressed mutants based on the method of Brenchley et al. (Brenchley, J.E., Prival, M.J. and Magasanik, B. (1973) J. Biol. Chem. 248, 6122-6128) for isolating histidase-constitutive mutants of a non-N2-fixing bacterium. 2. Nitrogenase levels of the new mutants in the presence of NH4+ were as high as 100% of the nitrogenase activity detected in the absence of NH4+. 3. Biochemical characterization of these nitrogen fixation (nif) derepressed mutants reveals that they fall into three classes. Three mutants (strains SK-24, 28 and 29), requiring glutamate for growth, synthesize nitrogenase and glutamine synthetase constitutively (in the presence of NH4+). A second class of mutants (strains SK-27 and 37) requiring glutamine for growth produces derepressed levels of nitrogenase activity and synthesized catalytically inactive glutamine synthetase protein, as determined immunologically. A third class of glutamine-requiring, nitrogenase-derepressed mutants (strain SK-25 and 26) synthesizes neither a catalytically active glutamine synthetase enzyme nor an immunologically cross-reactive glutamine synthetase protein. 4. F-prime complementation analysis reveals that the mutant strains SK-25, 26, 27, 37 map in a segment of the Klebsiella chromosome corresponding to the region coding for glutamine synthetase. Since the mutant strains SK-27 and SK-37 produce inactive glutamine synthetase protein, it is concluded that these mutations map within the glutamine synthetase structural gene.     

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 with an Altered Tryptophanyl-Transfer Ribonucleic Acid Synthetase

Fourteen mutant strains of Escherichia coli were examined, each of which requires tryptophan for growth but is unaltered in any of the genes of the tryptophan biosynthetic operon. The genetic lesions responsible for tryptophan auxotrophy in these strains map between str and malA. Extracts of these strains have little or no ability to charge transfer ribonucleic acid (tRNA) with tryptophan. We found that several of the mutants produce tryptophanyl-tRNA synthetases which are more heat-labile than the enzyme of the parental wild-type strain. Of these heat-labile synthetases, at least one is protected against thermal inactivation by tryptophan, magnesium, and adenosine triphosphate. Two other labile synthetases which are not noticeably protected against heat inactivation by substrate have decreased affinity for tryptophan. On low levels of supplied tryptophan, these mutants exhibit markedly decreased growth rates but do not contain derepressed levels of the tryptophan biosynthetic enzymes. This suggests that the charging of tryptophan-specific tRNA is not involved in repression, a conclusion which is further substantiated by our finding that 5-methyltryptophan, a compound which represses the tryptophan operon, is not attached to tRNA by the tryptophanyl-tRNA synthetase of E. coli.