Autogenous repression of Escherichia coli threonyl-tRNA synthetase expression in vitro

Escherichia coli threonyl-tRNA synthetase (EC 6.1.1.3) expression has been examined in an acellular protein-synthesizing system programmed with a plasmid DNA carrying thrS, infC, pheS, and pheT, the gene for threonyl-tRNA synthetase, initiation factor 3, and the two protomers of phenylalanyl-tRNA synthetase (EC 6.1.1.20), respectively. The initial rate of synthesis of L-[35S]methionine-labeled threonyl-tRNA synthetase is markedly reduced by the addition of homogeneous RNase-free threonyl-tRNA synthetase to the assay, not by that of phenylanyl- or tyrosyl-tRNA synthetase (EC 6.1.1.1). The inhibition is 50% in the presence of 0.25 microM threonyl-tRNA synthetase and reaches 90% with 2 microM enzyme. Synthesis of mRNA in the acellular DNA-dependent protein-synthesizing system has been measured by molecular hybridization to gene-specific lambda DNA probes corresponding to thrS, pheS, and pheT. The addition to the assay of 2 microM threonyl-tRNA synthetase does not affect the extent of mRNA hybridizing to the thrS-specific DNA probe. This result is interpreted as reflecting an effect of the synthetase on its expression at the translational level. Analysis of the DNA sequence of the thrS gene predicts several potential secondary structures capable of forming in the thrS mRNA. One of these potential structures is a cloverleaf. The possible role of such structures in controlling expression of thrS is discussed.     

Sequence analysis and modular organization of threonyl-tRNA synthetase from Thermus thermophilus and its interrelation with threonyl-tRNA synthetases of other origins.

The gene encoding threonyl-tRNA synthetase (Thr-tRNA synthetase) from the extreme thermophilic eubacterium Thermus thermophilus HB8 has been cloned and sequenced. The ORF encodes a polypeptide chain of 659 amino acids (Mr 75 550) that shares strong similarities with other Thr-tRNA synthetases. Comparative analysis with the three-dimensional structure of other subclass IIa synthetases shows it to be organized into four structural modules: two N-terminal modules specific to Thr-tRNA synthetases, a catalytic core and a C-terminal anticodon-binding module. Comparison with the three-dimensional structure of Escherichia coli Thr-tRNA synthetase in complex with tRNAThr enabled identification of the residues involved in substrate binding and catalytic activity. Analysis by atomic absorption spectrometry of the enzyme overexpressed in E. coli revealed the presence in each monomer of one tightly bound zinc atom, which is essential for activity. Despite strong similarites in modular organization, Thr-tRNA synthetases diverge from other subclass IIa synthetases on the basis of their N-terminal extensions. The eubacterial and eukaryotic enzymes possess a large extension folded into two structural domains, N1 and N2, that are not significantly similar to the shorter extension of the archaebacterial enzymes. Investigation of a truncated Thr-tRNA synthetase demonstrated that domain N1 is not essential for tRNA charging. Thr-tRNA synthetase from T. thermophilus is of the eubacterial type, in contrast to other synthetases from this organism, which exhibit archaebacterial characteristics. Alignments show conservation of part of domain N2 in the C-terminal moiety of Ala-tRNA synthetases. Analysis of the nucleotide sequence upstream from the ORF showed the absence of both any anticodon-like stem-loop structure and a loop containing sequences complementary to the anticodon and the CCA end of tRNAThr. This means that the expression of Thr-tRNA synthetase in T. thermophilus is not regulated by the translational and trancriptional mechanisms described for E. coli thrS and Bacillus subtilis thrS and thrZ. Here we discuss our results in the context of evolution of the threonylation systems and of the position of T. thermophilus in the phylogenic tree.     

Threonyl-transfer ribonucleic acid synthetase and the regulation of the threonine operon in Escherichia coli.

Two threonine-requiring mutants with derepressed expression of the threonine operon were isolated from an Escherichia coli K-12 strain containing two copies of the thr operon. One of them carries a leaky mutation in ilvA (the structural gene for threonine deaminase), which creates an isoleucine limitation and therefore derepression of the thr operon. In the second mutant, the enzymes of the thr operon were not repressed by threonine plus isoleucine; the threonyl-transfer ribonucleic acid(tRNA) synthetase from this mutant shows an apparent Km for threonine 200-fold higher than that of the parental strain. The gene, called thrS, coding for threonyl-tRNA synthetase was located around 30 min on the E. coli map. The regulatory properties of this mutant imply the involvement of charged threonyl-tRNA or threonyl-tRNA synthetase in the regulation of the thr operon.     

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.     

Escherichia coli phenylalanyl-tRNA synthetase operon: transcription studies of wild-type and mutated operons on multicopy plasmids

The construction of three lambda bacteriophages containing parts of the structural gene for threonyl-tRNA synthetase, thrS, and those for the two subunits of phenylalanyl-tRNA synthetases, pheS and pheT, is described. These phages were used as hybridization probes to measure the in vivo levels of mRNA specific to these three genes. Plasmid pB1 carries the three genes thrS, pheS, and pheT, and strains carrying the plasmid show enhanced levels of mRNA corresponding to these genes. Although the steady-state levels of threonyl-tRNA synthetase and phenylalanyl-tRNA synthetase produced by the presence of the plasmid differed by a factor of 10, their pulse-labeled mRNA levels were about the same. Mutant derivatives of pB1 were also analyzed. Firstly, a cis-acting insertion located before the structural genes for phenylalanyl-tRNA synthetase caused a major decrease in both pheS and pheT mRNA. Secondly, mutations affecting either structural gene pheS or pheT caused a reduction in the mRNA levels for both pheS and pheT. This observation suggests that autoregulation plays a role in the expression of phenylalanyl-tRNA synthetase.     

Bacillus subtilis phenylalanyl-tRNA synthetase genes: cloning and expression in Escherichia coli and B. subtilis.

The genes that encode the two subunits of Bacillus subtilis phenylalanyl-tRNA synthetase were cloned from alpha lambda library of chromosomal B. subtilis DNA by specific complementation of a thermosensitive Escherichia coli pheS mutation. Both genes (we named them pheS and pheT, analogous to the corresponding genes of E. coli) are carried by a 6.6-kilobase-pair PstI fragment which also complements E. coli pheT mutations. This fragment directs the synthesis of two proteins identical in size to the purified alpha and beta subunits of the phenylalanyl-tRNA synthetase of B. subtilis with Mrs of 42,000 and 97,000, respectively. A recombinant shuttle plasmid carrying the genes caused 10-fold overproduction of functional phenylalanyl-tRNA synthetase in B. subtilis.     

Phosphorylation of glutaminyl-tRNA synthetase and threonyl-tRNA synthetase by the gene products of dnaK and dnaJ in Escherichia coli K-12 cells

In Escherichia coli K-12, the heat shock protein DnaK and DnaJ participate in phosphorylation of both glutaminyl-tRNA synthetase and threonyl-tRNA synthetase since when cellular proteins extracted from the dnaK7(Ts), dnaK756(Ts) and dnaJ259(Ts) mutant cells labeled with 32Pi at 42 degrees C were analyzed by two-dimensional gel electrophoresis, no phosphorylation of glutaminyl-tRNA synthetase and threonyl-tRNA synthetase was observed while phosphorylation of both aminoacyl-tRNA synthetases was detected in the samples extracted from wild-type cells.     

The relationship between translational control and mRNA degradation for the Escherichia coli threonyl-tRNA synthetase gene.

Expression of thrS, the gene encoding Escherichia coli threonyl-tRNA synthetase, is negatively autoregulated at the translational level. Regulation is due to the binding of threonyl-tRNA synthetase to its own mRNA at a site called the operator, located immediately upstream of the initiation codon. The present work investigates the relationship between regulation and mRNA degradation. We show that two regulatory mutations, which increase thrS expression, cause an increase in the steady-state mRNA concentration. Unexpectedly, however, the half-life of thrS mRNA in the derepressed mutants is equal to that of the wild-type, indicating that mRNA stability is independent of the repression level. All our results can be explained if one assumes that thrS mRNA is either fully translated or immediately degraded. The immediately degraded RNAs are never detected due to their extremely short half-lives, while the fully translated messengers share the same half-lives, irrespective of the mutations. The increase in the steady-state level of thrS mRNA in the derepressed mutants is simply explained by an increase in the population of translated molecules, i.e. those never bound by the repressor, ThrRS. Despite this peculiarity, thrS mRNA degradation seems to follow the classical degradation pathway. Its stability is increased in a strain defective for RNase E, indicating that an endonucleolytic cleavage by this enzyme is the rate-limiting process in degradation. We also observe an accumulation of small fragments corresponding to the 5' end of the message in a strain defective for polynucleotide phosphorylase, indicating that, following the endonucleolytic cleavages, fragments are normally degraded by 3' to 5' exonucleolytic trimming. Although mRNA degradation was suspected to increase the efficiency of translational control based on several considerations, our results indicate that inhibition of mRNA degradation has no effect on the level of repression by ThrRS.     

Participation of the dnaK and dnaJ gene products in phosphorylation of glutaminyl-tRNA synthetase and threonyl-tRNA synthetase of Escherichia coli K-12.

The heat shock proteins DnaK and DnaJ of Escherichia coli participate in phosphorylation of both glutaminyl-tRNA synthetase and threonyl-tRNA synthetase. When cellular proteins extracted from the dnaK7(Ts) and dnaJ259(Ts) mutant cells labeled with 32Pi at 42 degrees C were analyzed by two-dimensional gel electrophoresis, no phosphorylation of these proteins was observed when they were compared with those from wild-type cells.     

The translational regulation of threonyl-tRNA synthetase. Functional relationship between the enzyme, the cognate tRNA and the ribosome

The E. coli threonyl-tRNA synthetase gene is negatively autoregulated at the translational level by a direct binding of the enzyme to the leader region of the thrS mRNA. This region folds in four well-defined domains. The enzyme binds to the leader at two major sites: the first is a stem-loop structure located in domain II upstream of the translational initiation site (domain I) which shares structural analogies with the anticodon arm of several tRNA(Thr) isoacceptors. The second site corresponds to a stable stem-loop structure located in domain IV. Both sites are separated by a large unpaired region (domain III). In vivo and in vitro experiments show that the structural integrity of both sites is required for the regulatory process. The binding of the enzyme to its mRNA target site represses its translation by preventing the ribosome from binding to its attachment site. tRNA(Thr) suppresses this inhibitory effect by displacing the mRNA from the enzyme at both the upstream stem-loop structure and the tRNA-like anticodon arm.     

Cloning and characterization of the gene for the yeast cytoplasmic threonyl-tRNA synthetase.

A fragment of DNA from the yeast nuclear gene MST1 that codes for the mitochondrial tRNAThr1 synthetase was used as a probe to screen for other yeast threonyl-tRNA synthetase genes. At low stringency, the MST1 probe hybridizes strongly to a 6.6 kb EcoRI fragment of yeast genomic DNA with the homologous gene and in addition hybridizes more weakly to a smaller 3.6 kb EcoRI fragment with a second threonyl-tRNA synthetase gene (THS1). To clone THS1, a library was constructed by ligation to pUC18 of size selected (3-4.5 kb) EcoRI fragments of genomic DNA. Several clones containing the 3.6 kb EcoRI fragment were isolated. A 2,202 nucleotide long open reading frame corresponding to THS1 has been identified in the cloned fragment of DNA. The predicted protein encoded by THS1 is 38% identical to the E. coli threonyl-tRNA synthetase over the latter's length (642 amino acids) and is 42% identical to the predicted MST1 product over its 462 residues. In situ disruption of the chromosomal copy of THS1 is lethal to the cell, indicating that this gene codes for the cytoplasmic threonyl-tRNA synthetase.     

Characterization of a yeast nuclear gene (MST1) coding for the mitochondrial threonyl-tRNA1 synthetase

The wild-type yeast nuclear gene MST1 complements mutants defective in mitochondrial protein synthesis. The gene has been sequenced and shown to code for a protein of 54,030 kDa. The predicted product of MST1 is 36% identical over its 462 residues to the Escherichia coli threonyl-tRNA synthetase. Amino-acylation of wild-type mitochondrial tRNAs with a mitochondrial extract from mst1 mutants fail to acylate tRNAThr1 (anticodon: 3'-GAU-5') but show normal acylation of tRNAThr2 (anticodon: 3'-UGU-5'). These data suggest the presence of two separate threonyl-tRNA synthetases in yeast mitochondria. Antibodies were prepared against a trpE/MST1 fusion protein containing the 321 residues from the amino-terminal region of the E. coli anthranilate synthetase and 118 residues of the mitochondrial threonyl-tRNA synthetase. Antibodies to the fusion protein detect a 50-55-kDa protein in wild type yeast mitochondria but not in mitochondria of a strain in which the chromosomal MST1 gene was replaced by a copy of the same gene disrupted by insertion of the yeast LEU2 gene. The ability of the mutant with the inactive MST1 gene to charge tRNAThr2 argues strongly for the existence of a second threonyl-tRNA synthetase gene.     

Domains of the Escherichia coli threonyl-tRNA synthetase translational operator and their relation to threonine tRNA isoacceptors.

The expression of the gene for threonyl-tRNA synthetase (thrS) is negatively autoregulated at the translational level in Escherichia coli. The synthetase binds to a region of the thrS leader mRNA upstream from the ribosomal binding site inhibiting subsequent translation. The leader mRNA consists of four structural domains. The present work shows that mutations in these four domains affect expression and/or regulation in different ways. Domain 1, the 3' end of the leader, contains the ribosomal binding site, which appears not to be essential for synthetase binding. Mutations in this domain probably affect regulation by changing the competition between the ribosome and the synthetase for binding to the leader. Domain 2, 3' from the ribosomal binding site, is a stem and loop with structural similarities to the tRNA(Thr) anticodon arm. In tRNAs the anticodon loop is seven nucleotides long, mutations that increase or decrease the length of the anticodon-like loop of domain 2 from seven nucleotides abolish control. The nucleotides in the second and third positions of the anticodon-like sequence are essential for recognition and the nucleotide in the wobble position is not, again like tRNA(Thr). The effect of mutations in domain 3 indicate that it acts as an articulation between domains 2 and 4. Domain 4 is a stable arm that has similarities to the acceptor arm of tRNA(Thr) and is shown to be necessary for regulation. Based on this mutational analysis and previous footprinting experiments, it appears that domains 2 and 4, those analogous to tRNA(Thr), are involved in binding the synthetase which inhibits translation probably by interfering with ribosome loading at the nearby translation initiation site.     

Isolation and molecular genetic characterization of the Bacillus subtilis gene (infB) encoding protein synthesis initiation factor 2.

Western blot (immunoblot) analysis of Bacillus subtilis cell extracts detected two proteins that cross-reacted with monospecific polyclonal antibody raised against Escherichia coli initiation factor 2 alpha (IF2 alpha). Subsequent Southern blot analysis of B. subtilis genomic DNA identified a 1.3-kilobase (kb) HindIII fragment which cross-hybridized with both E. coli and Bacillus stearothermophilus IF2 gene probes. This DNA was cloned from a size-selected B. subtilis plasmid library. The cloned HindIII fragment, which was shown by DNA sequence analysis to encode the N-terminal half of the B. subtilis IF2 protein and 0.2 kb of upstream flanking sequence, was utilized as a homologous probe to clone an overlapping 2.76-kb ClaI chromosomal fragment containing the entire IF2 structural gene. The HindIII fragment was also used as a probe to obtain overlapping clones from a lambda gt11 library which contained additional upstream and downstream flanking sequences. Sequence comparisons between the B. subtilis IF2 gene and the other bacterial homologs from E. coli, B. stearothermophilus, and Streptococcus faecium displayed extensive nucleic acid and protein sequence homologies. The B. subtilis infB gene encodes two proteins, IF2 alpha (78.6 kilodaltons) and IF2 beta (68.2 kilodaltons); both were expressed in B. subtilis and E. coli. These two proteins cross-reacted with antiserum to E. coli IF2 alpha and were able to complement in vivo an E. coli infB gene disruption. Four-factor recombination analysis positioned the infB gene at 145 degrees on the B. subtilis chromosome, between the polC and spcB loci. This location is distinct from those of the other major ribosomal protein and rRNA gene clusters of B. subtilis.