Effect of the overproduction of phenylalanyl- and threonyl-tRNA synthetases on tRNAPhe and tRNAThr concentrations in E. coli cells

Mutants of pheV in Escherichia coli affecting control by attenuation of the pheS, T and pheA operons. Two distinct mechanisms for de-attenuation

Two mutants of pheV, a gene coding for tRNA(Phe) in Escherichia coli, were previously isolated because they affect attenuator control of the pheS, T operon when the mutant pheV genes are carried by the plasmid pBR322. We show that the two mutants (A44 and A46) affect attenuator control by different mechanisms. The effect of mutant A44 on pheS, T expression can be progressively decreased by overproduction of Phe-tRNA synthetase, consistent with the mutant tRNA acting as a competitive inhibitor of the enzyme. By contrast, the effect on attenuation of mutant A46 increases with overproduction of Phe-tRNA synthetase, indicating that the mutant must be charged to affect attenuation; we propose that this mutant affects translation directly and causes derepression by competing with wild-type tRNA in translation of the attenuator region leader peptide. Mutant A46 but not mutant A44 leads to further de-attenuation in a miaA background. The presence of two different mechanisms for de-attenuation is further indicated by the finding that a second attenuator controlled by Phe codon translation, from the pheA operon, is affected quite differently by the mutant tRNAs. Finally, experiments involving the introduction of the mutations A44 and A46 into an amber suppressor derived from tRNA(Phe) suggest that both species can function in protein synthesis but with reduced efficiency; mutant A46 is less efficient than mutant A44, consistent with a defect in elongation.

Transcription and regulation of expression of the Escherichia coli methionyl-tRNA synthetase gene

The DNA sequence and transcriptional organization around the Escherichia coli methionyl-tRNA synthetase gene, metG, were resolved. This gene can be transcribed in vivo and in vitro from two distinct promoters separated by 510 nucleotides. The upstream promoter is located within the coding sequence of a divergent gene expressing a protein of Mr 39 kDa of unknown function. Transcription originating from this upstream promoter is attenuated by a Rho-independent terminator before entering the structural gene. This leader RNA contains several potentially stable secondary structures, one of which shows striking similarity to tRNA(Met), but no methionine-rich coding sequence. The regulation of metG expression was investigated by means of fusions to the lacZ gene. Transcription of a metG::lacZ fusion is induced in a metG mutant and, reciprocally, repression is observed in a methionyl-tRNA synthetase overproducing strain. A model of metG expression control is proposed.

Low-resolution structure of the tetrameric phenylalanyl-tRNA synthetase from Escherichia coli. A neutron small-angle scattering study of hybrids composed of protonated and deuterated protomers

Escherichia coli phenylalanyl-tRNA synthetase is a tetrameric protein composed of two types of protomers. In order to resolve the subunit organization, neutron small-angle scattering experiments have been performed in different contrasts with all types of isotope hybrids that could be obtained by reconstituting the alpha 2 beta 2 enzyme from the protonated and deuterated forms of the alpha and beta subunits. Experiments have been also made with the isolated alpha promoter. A model for the alpha 2 beta 2 tetramer is deduced where the two alpha promoters are elongated ellipsoids (45 x 45 x 160 A3) lying side by side with an angle of about 40 degrees between their long axes and where the two beta subunits are also elongated ellipsoids (31 x 31 x 130 A3) with an angle of 30 degrees between their axes. This model was obtained by assuming that the two pairs of subunits are in contact in an orthogonal manner and by taking advantage of the measured distance between the centers of mass of the alpha 2 and beta 2 pairs (d = 23 +/- 2 A).

Genetic engineering of methionyl-tRNA synthetase: in vitro regeneration of an active synthetase by proteolytic cleavage of a methionyl-tRNA synthetase--beta-galactosidase chimeric protein

The construction of a family of plasmids carrying derivatives of metG, the gene for E. coli methionyl-tRNA synthetase, is described. These plasmids allow expression of native or truncated forms of the enzyme and easy purification of the products. To facilitate the characterization of modified enzymes with very low catalytic activity, a specialized vector was constructed, in which metG was fused in frame with lacZ, the gene for beta-galactosidase. This plasmid expresses a methionyl-tRNA synthetase-beta-galactosidase chimeric protein, which is shown to carry the activities of both enzymes. This hybrid can be purified in a single step of affinity chromatography for beta-galactosidase. The methionyl-tRNA synthetase moiety can be regenerated by mild proteolysis, thus providing a simple method for purifying and studying mutated proteins.

Dual level control of the Escherichia coli pheST-himA operon expression. tRNA(Phe)-dependent attenuation and transcriptional operator-repressor control by himA and the SOS network

Previous studies of phenylalanyl-tRNA synthetase expression in Escherichia coli have established that the pheST operon transcription is controlled by a Phe-tRNA(Phe)-mediated attenuation mechanism. More recently, the himA gene, encoding the alpha-subunit of integration host factor, was recognized immediately downstream from pheT, possibly forming part of the same transcriptional unit. By using the in-vitro transcription and S1 mapping techniques, transcription termination after pheT could be excluded, indicating that himA can be expressed from polycistronic messenger RNAs encompassing the pheST region. However, the presence of a secondary promoter able to express himA and located within pheT is demonstrated. To further investigate the regulation of the pheST-himA operon expression, genetic fusions between various parts of this operon and the lacZ gene were constructed and studied. Our results confirm the autoregulation of himA previously described, and demonstrate that it occurs through the modulation of the secondary promoter activity within pheT. Surprisingly, it is found that the pheST promoter is also submitted to the same control. Consistent with this, DNA sequences homologous to the integration host factor binding site consensus are present at the level of both promoters. However, evidence in favor of two different repressor complexes is provided. Previously observed SOS induction of the himA expression is shown to occur through the modulation of both promoter activities. Contrasting with the other genes under SOS control, the LexA protein binding site consensus sequence could not be found in the two promoter regions. This suggests that either the LexA protein directly participates in the formation of an active holorepressor, or that the product of an SOS gene is able to inhibit the formation or the binding of such a repressor. Finally, our results indicate that the pheST-himA operon expression is controlled by two different mechanisms acting independently. (1) The phenylalanyl-tRNA synthetase and the himA product expressions are controlled by an operator-repressor type mechanism, in which the himA product and the SOS network are involved. (2) Through its partial cotranscription with pheST, himA expression is also under attenuation control. The latter control may provide a way to couple the intracellular concentration of the himA product to the functional state of the translational apparatus.

Autogenous control of Escherichia coli threonyl-tRNA synthetase expression in vivo

The regulation of the expression of thrS, the structural gene for threonyl-tRNA synthetase, was studied using several thrS-lac fusions cloned in lambda and integrated as single copies at att lambda. It is first shown that the level of beta-galactosidase synthesized from a thrS-lac protein fusion is increased when the chromosomal copy of thrS is mutated. It is also shown that the level of beta-galactosidase synthesized from the same protein fusion is decreased if wild-type threonyl-tRNA synthetase is overproduced from a thrS-carrying plasmid. These results strongly indicate that threonyl-tRNA synthetase controls the expression of its own gene. Consistent with this hypothesis it is shown that some thrS mutants overproduce a modified form of threonyl-tRNA synthetase. When the thrS-lac protein fusion is replaced by several types of thrS-lac operon fusions no effect of the chromosomal thrS allele on beta-galactosidase synthesis is observed. It is also shown that beta-galactosidase synthesis from a promoter-proximal thrS-lac operon fusion is not repressed by threonyl-tRNA synthetase overproduction. The fact that regulation is seen with a thrS-lac protein fusion and not with operon fusions indicates that thrS expression is autoregulated at the translational level. This is confirmed by hybridization experiments which show that under conditions where beta-galactosidase synthesis from a thrS-lac protein fusion is derepressed three- to fivefold, lac messenger RNA is only slightly increased.

Attenuation control of the Escherichia coli phenylalanyl-tRNA synthetase operon

The pheST operon codes for the two subunits of the essential enzyme phenylalanyl-tRNA synthetase. The nucleotide sequence of the regulatory regions of the operon, in vitro transcription data and in vivo experiments indicate that the operon is controlled by attenuation in a way similar to many amino acid biosynthetic operons. In this work the control of the pheST operon was studied in vivo by measuring the effect of deletions in the regulatory regions on downstream expression. The presence of a strong promoter followed by an approximately 90% efficient terminator in front of the structural parts of the operon is demonstrated. An open reading frame coding for a 14 amino acid long leader peptide containing five phenylalanine residues is located between the promoter and the terminator. The presence of the transcription terminator is shown to be essential to the operon's regulation. The localization of the promoter and the terminator agrees with the results of previous in vitro experiments. It is also shown that about 30% of the transcripts covering the pheST operon come from the upstream gene, rplT, which codes for the ribosomal protein L20. Although cotranscription exists between rplT and pheST, these genes are not systematically coregulated since reducing the translation of rplT about tenfold, does not change pheST expression. The pheST operon is also shown to be derepressed by a cellular excess of phenylalanyl-tRNA synthetase. This derepression is shown to be due to the pheST attenuator.

IS4 transposition in the attenuator region of the Escherichia coli pheS,T operon

A cis-acting mutation which lowers phenylalanyl-tRNA synthetase operon (pheS,T) transcription about tenfold was previously isolated on a multicopy plasmid [Plumbridge and Springer, J. Bacteriol. 152 (1982) 650-668]. This mutation has now been characterized as an IS4 element inserted in orientation II in the terminator stem of the pheS,T attenuator. The identification of the insertion as IS4 is based on (i) the nature and location of restriction sites internal to the insertion element, and (ii) the DNA sequence of both the left and right Escherichia coli::IS4 junctions. The effect of the IS4 transposition on the expression of pheS,T was studied using pheS,T::lac fusions cloned in lambda phages. IS4 integration into the leader region of the pheS,T operon was shown to abolish the miaA (trpX) allele dependence which characterizes the attenuation mechanism regulating pheS,T expression [Fayat et al., J. Mol. Biol. 171 (1983) 239-261; Springer et al., J. Mol. Biol. 171 (1983) 263-279]. The IS4 insertion site described here is compared to the other known sites and the effect of IS4 transposition on the expression of neighbouring genes is discussed.

Molecular cloning and characterization of the gene for Escherichia coli valyl-tRNA synthetase

A ColE1 hybrid, pB2, carrying the structural gene for the valyl-tRNA synthetase, valS, and the pyrBI operon was isolated from the Clarke-Carbon collection. Strain GRB238 with a temperature-sensitive mutation in the valS gene showed a three-fold increase in valyl-tRNA synthetase activity after transformation with pB2. The valS gene was subcloned into pBR322 after partial Sau3A digestion of pB2. The new plasmid, pHOV1 had a 9.4-kb insert in pBR322 and cells carrying pHOV1 showed an eight-fold increase in specific valyl-tRNA synthetase activity. The localization and direction of transcription of valS in pHOV1 was determined by transposon-directed mutagenesis and analysis of protein synthesis in minicells. The valS gene was shown to be transcribed opposite to the direction of DNA replication, i.e., counterclockwise.

Purification and reversible subunit dissociation of overproduced Escherichia coli phenylalanyl-tRNA synthetase

Phenylalanyl-tRNA synthetase (EC 6.1.1.20) has been purified to homogeneity from a 100-fold overproducing Escherichia coli strain carrying a hybrid pBR322 plasmid containing the pheS-pheT locus. The purified enzyme is identical to the phenylalanyl-tRNA synthetase isolated form an haploid strain. The enzyme was found to dissociate in the presence of 0.5 M NaSCN and the alpha- and beta-subunits composing the native alpha 2 beta 2 enzyme were separated by gel filtration. Neither isolated subunit showed significant catalytic activity. A complex indistinguishable from the native enzyme with full catalytic activity is recovered upon mixing the subunits. The N- and C-terminal sequences and the amino acid composition of each subunit were determined. They are compared to the available data concerning the primary structure of the subunits, as deduced from nucleotide sequencing of the pheS-pheT operon.